Image processing device and method

ABSTRACT

Provided is an image processing device including a receiving section configured to receive a bitstream obtained by encoding an image having at least one layer and buffer management parameter information of each layer indicating at least one of that a parameter for managing a decoder buffer is a parameter for performing a decoding process of only a corresponding layer and that the parameter for managing the decoder buffer is a parameter for performing a decoding process of a corresponding layer and a lower layer, and a decoding section configured to decode the bitstream received by the receiving section and generate an image.

TECHNICAL FIELD

The present disclosure relates to an image processing device and method,and more particularly, to an image processing device and method whichare capable of performing a decoding process at a proper timing inscalable video coding.

BACKGROUND ART

Recently, devices for compressing and encoding an image by adopting aencoding scheme of handling image information digitally and performingcompression by an orthogonal transform such as a discrete cosinetransform and motion compensation using image information-specificredundancy for the purpose of information transmission and accumulationwith high efficiency when the image information is handled digitallyhave become widespread. Moving Picture Experts Group (MPEG), H.264,MPEG-4 Part 10 (Advanced Video Coding) (hereinafter referred to asH.264/AVC), and the like are examples of such encoding schemes.

Therefore, for the purpose of improving encoding efficiency compared toH.264/AVC, standardization of a encoding scheme referred to as highefficiency video coding (HEVC) by Joint Collaboration Team-Video Coding(JCTVC), which is a joint standardizing organization of InternationalTelecommunication Union Telecommunication Standardization Sector (ITU-T)and International Organization for Standardization (ISO)/InternationalElectrotechnical Commission (IEC), is currently in progress, andNon-Patent Literature 1 has been issued as a draft of the scheme.

Meanwhile, the existing image encoding schemes such as MPEG-2 and AVChave a scalability function of dividing an image into a plurality oflayers and encoding the plurality of layers.

In other words, for example, for a terminal having a low processingcapability such as a mobile phone, image compression information of onlya base layer is transmitted, and a moving image of low spatial andtemporal resolutions or a low quality is reproduced, and for a terminalhaving a high processing capability such as a television or a personalcomputer, image compression information of an enhancement layer as wellas a base layer is transmitted, and a moving image of high spatial andtemporal resolutions or a high quality is reproduced. That is, imagecompression information according to a capability of a terminal or anetwork can be transmitted from a server without performing thetranscoding process.

In the HEVC, it is possible to designate a hypothetical referencedecoder (HRD) parameter so that an overflow or an underflow of a bufferdoes not occur when a decoding process for image compression informationis performed. Particularly, it is possible to designate an HRD parameterfor each layer when scalable video coding is performed (see Non-PatentLiterature 2).

CITATION LIST Non-Patent Literature

-   Non-Patent Literature 1: Benjamin Bross, Woo-Jin Han, Jens-Rainer    Ohm, Gary J. Sullivan, Thomas Wiegand,” High efficiency video coding    (HEVC) text specification draft 9,” JCTVC-K 1003, 2012, 10, 21-   Non-Patent Literature 2: Jill Boyce, Ye-Kui Wang, “NAL unit header    and parameter set designs for HEVC extensions,” JCTVC-K 1007, 2012,    10, 19

SUMMARY OF INVENTION Technical Problem

However, when the HRD parameter is designated for each layer or a timelayer serving as one of sublayers, it is difficult to detect whether thedecoding process is performed by a single decoding device or a pluralityof decoding devices.

The present disclosure was made in light of the foregoing, and it isdesirable to perform a decoding process at a proper timing.

Solution to Problem

According to one aspect of the present disclosure, there is provided animage processing device including a receiving section configured toreceive a bitstream obtained by encoding an image having at least onelayer and buffer management parameter information of each layerindicating at least one of that a parameter for managing a decoderbuffer is a parameter for performing a decoding process of only acorresponding layer and that the parameter for managing the decoderbuffer is a parameter for performing a decoding process of acorresponding layer and a lower layer, and a decoding section configuredto decode the bitstream received by the receiving section and generatean image.

The layer can include a layer and a sublayer.

The layer is a view of multi-view coding.

The layer is a layer of scalable video coding.

The buffer management parameter information is described in supplementalenhancement information (SEI).

The buffer management parameter information is described inbuffering_period_SEI.

Parameter presence/absence information indicating a presence or absenceof the parameter for managing the decoder buffer serving as theparameter for performing the decoding process of only the correspondinglayer is described in a vps (video parameter set)_extension.

The receiving section can receive an AVC flag indicating that a layerlower than the corresponding layer is encoded by MPEG-4 Part10 AdvancedVideo Coding (AVC) and the buffer management parameter information ofeach layer indicating that the parameter for managing the decoder bufferis the parameter for performing the decoding process of only thecorresponding layer.

According to one aspect of the present disclosure, there is provided animage processing method including receiving, by an image processingdevice, a bitstream obtained by encoding an image having at least onelayer and buffer management parameter information of each layerindicating at least one of that a parameter for managing a decoderbuffer is a parameter for performing a decoding process of only acorresponding layer and that the parameter for managing the decoderbuffer is a parameter for performing a decoding process of acorresponding layer and a lower layer, receiving, by the imageprocessing device, a bitstream obtained by encoding an image includingat least one layer using a parameter corresponding to the buffermanagement parameter information, and decoding, by the image processingdevice, the received bitstream and generating an image.

According to another aspect of the present disclosure, there is providedan image processing device including a setting section configured to setbuffer management parameter information of each layer indicating atleast one of that a parameter for managing a decoder buffer is aparameter for performing a decoding process of only a correspondinglayer and that the parameter for managing the decoder buffer is aparameter for performing a decoding process of a corresponding layer anda lower layer, an encoding section configured to encode an image havingat least one layer and generate a bitstream, and a transmitting sectionconfigured to transmit the buffer management parameter information setby the setting section and the bitstream generated by the encodingsection.

The layer can include a layer and a sublayer.

The layer is a view of multi-view coding.

The layer is a layer of scalable video coding.

The buffer management parameter information is described in supplementalenhancement information (SEI).

The buffer management parameter information is described inbuffering_period_SEI.

Parameter presence/absence information indicating a presence or absenceof the parameter for managing the decoder buffer serving as theparameter for performing the decoding process of only the correspondinglayer is described in a vps (video parameter set)_extension.

The setting section can set an AVC flag indicating that a layer lowerthan the corresponding layer is encoded by MPEG-4 Part10 Advanced VideoCoding (AVC) and the buffer management parameter information of eachlayer indicating that the parameter for managing the decoder buffer isthe parameter for performing the decoding process of only thecorresponding layer.

According to another aspect of the present disclosure, there is providedan image processing method including setting, by an image processingdevice, buffer management parameter information of each layer indicatingat least one of that a parameter for managing a decoder buffer is aparameter for performing a decoding process of only a correspondinglayer and that the parameter for managing the decoder buffer is aparameter for performing a decoding process of a corresponding layer anda lower layer, encoding, by the image processing device, an image havingat least one layer and generating a bitstream, and transmitting, by theimage processing device, the set buffer management parameter informationand the generated bitstream.

According to one aspect of the present disclosure, a bitstream obtainedby encoding an image having at least one layer and buffer managementparameter information of each layer indicating at least one of that aparameter for managing a decoder buffer is a parameter for performing adecoding process of only a corresponding layer and that the parameterfor managing the decoder buffer is a parameter for performing a decodingprocess of a corresponding layer and a lower layer are received. Then,the received bitstream is decoded to generate an image.

According to another aspect of the present disclosure, buffer managementparameter information of each layer indicating at least one of that aparameter for managing a decoder buffer is a parameter for performing adecoding process of only a corresponding layer and that the parameterfor managing the decoder buffer is a parameter for performing a decodingprocess of a corresponding layer and a lower layer is set, and an imagehaving at least one layer is encoded to generate a bitstream. Then, theset buffer management parameter information and the generated bitstreamare transmitted.

Also, the above-described image processing device may be an independentdevice or an inner block constituting one image encoding device or imagedecoding device.

Advantageous Effects of Invention

According to one aspect of the present disclosure, it is possible todecode an image. Particularly, it is possible to perform a decodingprocess at a proper timing.

According to another aspect of the present disclosure, it is possible toencode an image. Particularly, it is possible to perform a decodingprocess at a proper timing.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a diagram for describing an example of a configuration of acoding unit.

FIG. 2 is a diagram for describing an example of spatial scalable videocoding.

FIG. 3 is a diagram for describing an example of temporal scalable videocoding.

FIG. 4 is a diagram for describing an example of scalable video codingof a signal to noise ratio.

FIG. 5 is a diagram illustrating an example of syntax of an HRDparameter of a HEVC.

FIG. 6 is a diagram for describing a parallel process of scalabilityvideo coding.

FIG. 7 is a diagram illustrating an example of syntax of an HRDparameter according to the present technology.

FIG. 8 is a diagram illustrating another example of syntax of an HRDparameter according to the present technology.

FIG. 9 is a diagram illustrating another example of syntax of an HRDparameter according to the present technology.

FIG. 10 is a block diagram illustrating an example of a mainconfiguration of a scalable encoding device.

FIG. 11 is a block diagram illustrating an example of a mainconfiguration of an enhancement layer image encoding section.

FIG. 12 is a block diagram illustrating an example of a mainconfiguration of an accumulation buffer and an HRD type setting section.

FIG. 13 is a diagram for describing an example of a layer structure.

FIG. 14 is a flowchart for describing an example of a flow of anencoding process.

FIG. 15 is a flowchart for describing an example of a layer encodingprocess.

FIG. 16 is a flowchart for describing an HRD parameter encoding process.

FIG. 17 is a flowchart for describing an HRD parameter calculationprocess.

FIG. 18 is a flowchart for describing an HRD parameter of the time layercalculation process.

FIG. 19 is a flowchart for describing another example of an HRDparameter encoding process.

FIG. 20 is a block diagram illustrating an example of a mainconfiguration of a scalable decoding device.

FIG. 21 is a block diagram illustrating an example of a mainconfiguration of an enhancement layer image decoding section.

FIG. 22 is a block diagram illustrating an example of a mainconfiguration of an accumulation buffer and an HRD type decodingsection.

FIG. 23 is a flowchart for describing an example of a flow of a decodingprocess.

FIG. 24 is a flowchart for describing an example of a flow of a layerdecoding process.

FIG. 25 is a flowchart for describing another example of a flow of anHRD parameter decoding process.

FIG. 26 is a flowchart for describing another example of a flow of anaccumulation buffer monitoring process.

FIG. 27 is a diagram illustrating an example of syntax of vps_extension.

FIG. 28 is a diagram illustrating an example of syntax of sps_extension.

FIG. 29 is a diagram illustrating an example of syntax of vps.

FIG. 30 is a diagram illustrating an example of semantics oflayer_id_included_flag.

FIG. 31 is a diagram for describing a setting example of LayerSet.

FIG. 32 is a diagram illustrating an example of syntax ofbuffering_period_SEI.

FIG. 33 is a diagram illustrating an example of syntax ofbuffering_period_SEI.

FIG. 34 is a diagram illustrating an example of syntax ofbuffering_period_SEI.

FIG. 35 is a diagram illustrating an example of syntax ofbuffering_period_SEI.

FIG. 36 is a block diagram illustrating another example of a mainconfiguration of an enhancement layer image encoding section.

FIG. 37 is a block diagram illustrating an example of a configuration ofa buffering period SEI setting section.

FIG. 38 is a flowchart for describing an example of a layer encodingprocess.

FIG. 39 is a flowchart for describing an example of a buffering periodSEI encoding process.

FIG. 40 is a block diagram illustrating another example of a mainconfiguration of an enhancement layer image decoding section.

FIG. 41 is a block diagram illustrating an example of a configuration ofa buffering period SEI decoding section.

FIG. 42 is a flowchart for describing an example of a layer decodingprocess.

FIG. 43 is a flowchart for describing an example of a buffering periodSEI decoding process.

FIG. 44 is a flowchart for describing an example of an HRD parameterencoding process in the case of an AVC flag.

FIG. 45 is a flowchart for describing an example of a buffering periodSEI encoding process in the case of an AVC flag.

FIG. 46 is a diagram illustrating an example of a multi-view imageencoding scheme.

FIG. 47 is a diagram illustrating an example of a main configuration ofa multi-view image encoding device to which the present disclosure isapplied.

FIG. 48 is a diagram illustrating an example of a main configuration ofa multi-view image decoding device to which the present disclosure isapplied.

FIG. 49 is a block diagram illustrating an example of a mainconfiguration of a computer.

FIG. 50 is a block diagram illustrating an example of a schematicconfiguration of a television device.

FIG. 51 is a block diagram illustrating an example of a schematicconfiguration of a mobile phone.

FIG. 52 is a block diagram illustrating an example of a schematicconfiguration of a recording/reproduction device.

FIG. 53 is a block diagram illustrating an example of a schematicconfiguration of an image capturing device.

FIG. 54 is a block diagram illustrating an example of using scalablevideo coding.

FIG. 55 is a block diagram illustrating another example of usingscalable video coding.

FIG. 56 is a block diagram illustrating another example of usingscalable video coding.

DESCRIPTION OF EMBODIMENTS

Hereinafter, modes (hereinafter referred to as “embodiments”) forcarrying out the present disclosure will be described. The descriptionwill proceed in the following order:

0. Overview

1. First embodiment (image encoding device)

2. Second embodiment (image decoding device)

3. Third embodiment (example of syntax)

4. Fourth embodiment (example of buffering_period_SEI)

5. Fifth embodiment (example of AVC flag)

6. Sixth embodiment (multi-view image encoding device/multi-view imagedecoding device)

7. Seventh embodiment (computer)

8. Applications

9. Applications of scalable video coding

0. Overview Encoding scheme

Hereinafter, the present technology will be described in connection withan application to image encoding and decoding of a High Efficiency VideoCoding (HEVC) scheme.

<Coding Unit>

In an Advanced Video Coding (AVC) scheme, a hierarchical structure basedon a macroblock and a sub macroblock is defined. However, a macroblockof 16×16 pixels is not optimal for a large image frame such as a UltraHigh Definition (UHD) (4000×2000 pixels) serving as a target of a nextgeneration encoding scheme.

On the other hand, in the HEVC scheme, a coding unit (CU) is defined asillustrated in FIG. 1.

A CU is also referred to as a coding tree block (CTB), and serves as apartial area of an image of a picture unit undertaking the same role ofa macroblock in the AVC scheme. The latter is fixed to a size of 16×16pixels, but the former is not fixed to a certain size but designated inimage compression information in each sequence.

For example, a largest coding unit (LCU) and a smallest coding unit(SCU) of a CU are specified in a sequence parameter set (SPS) includedin encoded data to be output.

As split-flag=1 is set in a range in which each LCU is not smaller thanan SCU, a coding unit can be divided into CUs having a smaller size. Inthe example of FIG. 1, a size of an LCU is 128, and a largest scalabledepth is 5. A CU of a size of 2N×2N is divided into CUs having a size ofN×N serving as a layer that is one-level lower when a value ofsplit_flag is 1.

Further, a CU is divided in prediction units (PUs) that are areas(partial areas of an image of a picture unit) serving as processingunits of intra or inter prediction, and divided into transform units(TUs) that are areas (partial areas of an image of a picture unit)serving as processing units of orthogonal transform. Currently, in theHEVC scheme, in addition to 4×4 and 8×8, orthogonal transform of 16×16and 32×32 can be used.

As in the HEVC scheme, in the case of an encoding scheme in which a CUis defined and various kinds of processes are performed in units of CUs,in the AVC scheme, a macroblock can be considered to correspond to anLCU, and a block (sub block) can be considered to correspond to a CU.Further, in the AVC scheme, a motion compensation block can beconsidered to correspond to a PU. Here, since a CU has a hierarchicalstructure, a size of an LCU of a topmost layer is commonly set to belarger than a macroblock in the AVC scheme, for example, such as 128×128pixels.

Thus, hereinafter, an LCU is assumed to include a macroblock in the AVCscheme, and a CU is assumed to include a block (sub block) in the AVCscheme. In other words, a “block” used in the following descriptionindicates an arbitrary partial area in a picture, and, for example, asize, a shape, and characteristics thereof are not limited. In otherwords, a “block” includes an arbitrary area (a processing unit) such asa TU, a PU, an SCU, a CU, an LCU, a sub block, a macroblock, or a slice.Of course, a “block” includes other partial areas (processing units) aswell. When it is necessary to limit a size, a processing unit, or thelike, it will be appropriately described.

<Mode Selection>

Meanwhile, in the AVC and HEVC encoding schemes, in order to achievehigh encoding efficiency, it is important to select an appropriateprediction mode.

As an example of such a selection method, there is a method implementedin reference software (found athttp://iphome.hhi.de/suehring/tml/index.htm) of H.264/MPEG-4 AVC calleda joint model (JM).

In the JM, as will be described later, it is possible to select two modedetermination methods, that is, a high complexity mode and a lowcomplexity mode. In both modes, cost function values related torespective prediction modes are calculated, and a prediction mode havinga smaller cost function value is selected as an optimal mode for acorresponding block or macroblock.

A cost function in the high complexity mode is represented as in thefollowing Formula (1):

Cost(ModeεΩ)=D+λ*R  (1)

Here, Ω indicates a universal set of candidate modes for encoding acorresponding block or macroblock, and D indicates differential energybetween a decoded image and an input image when encoding is performed ina corresponding prediction mode. λ indicates Lagrange's undeterminedmultiplier given as a function of a quantization parameter. R indicatesa total coding amount including an orthogonal transform coefficient whenencoding is performed in a corresponding mode.

In other words, in order to perform encoding in the high complexitymode, it is necessary to perform a temporary encoding process once byall candidate modes in order to calculate the parameters D and R, andthus a large computation amount is required.

A cost function in the low complexity mode is represented by thefollowing Formula (2):

Cost(ModeεΩ)=D+QP2Quant(QP)*HeaderBit  (2)

Here, D is different from that of the high complexity mode and indicatesdifferential energy between a prediction image and an input image.QP2Quant (QP) is given as a function of a quantization parameter QP, andHeaderBit indicates a coding amount related to information belonging toa header such as a motion vector or a mode including no orthogonaltransform coefficient.

In other words, in the low complexity mode, it is necessary to perform aprediction process for respective candidate modes, but since a decodedimage is not necessary, it is unnecessary to perform an encodingprocess. Thus, it is possible to implement a computation amount smallerthan that in the high complexity mode.

<Scalable Video Coding>

Meanwhile, the existing image encoding schemes such as MPEG2 and AVChave a scalability function as illustrated in FIGS. 2 to 4. Scalablevideo coding refers to a scheme of dividing (hierarchizing) an imageinto a plurality of layers and performing encoding for each layer.

In hierarchization of an image, one image is divided into a plurality ofimages (layers) based on a certain parameter. Basically, each layer isconfigured with differential data so that redundancy is reduced. Forexample, when one image is hierarchized into two layers, that is, a baselayer and an enhancement layer, an image of a lower quality than anoriginal image is obtained using only data of the base layer, and anoriginal image (that is, a high-quality image) is obtained by combiningdata of the base layer with data of the enhancement layer.

As an image is hierarchized as described above, it is possible to obtainimages of various qualities according to the situation. For example, fora terminal having a low processing capability such as a mobile phone,image compression information of only a base layer is transmitted, and amoving image of low spatial and temporal resolutions or a low quality isreproduced, and for a terminal having a high processing capability suchas a television or a personal computer, image compression information ofan enhancement layer as well as a base layer is transmitted, and amoving image of high spatial and temporal resolutions or a high qualityis reproduced. In other words, image compression information accordingto a capability of a terminal or a network can be transmitted from aserver without performing the transcoding process.

As a parameter having scalability, for example, there is spatialresolution (spatial scalability) as illustrated in FIG. 2. When thespatial scalability differs, respective layers have differentresolutions. In other words, each picture is hierarchized into twolayers, that is, a base layer of a resolution spatially lower than thatof an original image and an enhancement layer that is combined with animage of the base layer to obtain an original image (an original spatialresolution) as illustrated in FIG. 2. Of course, the number of layers isan example, and each picture can be hierarchized into an arbitrarynumber of layers.

As another parameter having such scalability, for example, there is atemporal resolution (temporal scalability) as illustrated in FIG. 3. Inthe case of the temporal scalability, respective layers have differentframe rates. In other words, in this case, each picture is hierarchizedinto layers having different frame rates, a moving image of a high framerate can be obtained by combining a layer of a high frame rate with alayer of a low frame rate, and an original moving image (an originalframe rate) can be obtained by combining all the layers as illustratedin FIG. 3. The number of layers is an example, and each picture can behierarchized into an arbitrary number of layers.

Further, as another parameter having such scalability, for example,there is a signal-to-noise ratio (SNR) (SNR scalability). In the case ofthe SNR scalability, respective layers having different SNRs. In otherwords, in this case, each picture is hierarchized into two layers, thatis, a base layer of an SNR lower than that of an original image and anenhancement layer that is combined with an image of the base layer toobtain an original SNR as illustrated in FIG. 4. In other words, forbase layer image compression information, information related to animage of a low PSNR is transmitted, and a high PSNR image can bereconstructed by combining the information with the enhancement layerimage compression information. Of course, the number of layers is anexample, and each picture can be hierarchized into an arbitrary numberof layers.

A parameter other than the above-described examples may be applied as aparameter having scalability. For example, there is bit-depthscalability in which the base layer includes an 8-bit image, and a10-bit image can be obtained by adding the enhancement layer to the baselayer.

Further, there is chroma scalability in which the base layer includes acomponent image of a 4:2:0 format, and a component image of a 4:2:2format can be obtained by adding the enhancement layer to the baselayer.

Further, as a parameter having scalability, there is a multi-view. Inthis case, an image is hierarchized into layers of different views.

For example, layers described in the present embodiment include spatial,temporal, SNR, bit depth, color, and view of scalability video codingdescribed above.

Further, a term “layer” used in this specification includes a layer ofscalable video coding and each view when a multi-view of a multi-view isconsidered.

Further, the term “layer” used in this specification is assumed toinclude a main layer (corresponding to sub) and a sublayer. As aspecific example, a main layer may be a layer of spatial scalability,and a sublayer may be configured with a layer of temporal scalability.

In the present embodiment, a layer (Japanese) and a layer have the samemeaning, a layer (Japanese) will be appropriately described as a layer.

<HRD Parameter>

Meanwhile, in the HEVC, when the decoding process of image compressioninformation is performed, it is possible to designate a HypotheticalReference Decoder (HDR) parameter illustrated in FIG. 5 so that nooverflow or underflow of a buffer occurs. In other words, the HRDparameter is a parameter used to manage a decoder buffer. Particularly,when scalable video coding is performed, it is possible to designate theHRD parameter for each layer in a video parameter set (VPS).

<Parallel Process of Scalability Video Coding>

In an example of FIG. 6, two examples (ex1 and ex2) using a sequenceincluding an I picture, a b picture, a B picture, a b picture, and a Bpicture are illustrated on the left side of FIG. 6 as an example oftemporal scalability. In this sequence, the I picture, the B picture,and the B picture are a lower time layer, and the b picture and the bpicture are an upper time layer.

Here, the B picture indicates a picture that is referred to, and the bpicture indicates a picture that is not referred to.

ex1 is an example in which all the pictures are decoded by a decodingdevice #0. On the other hand, ex2 is an example in which the lower timelayer of the I picture, the B picture, and the B picture is decoded bythe decoding device #0, and the upper time layer of the b picture andthe b picture is decoded by a decoding device #1.

On the right side of FIG. 6, as a scalable HEVC example, two examples(ex11 and ex12) using a sequence including the I picture, the B picture,and the B picture of the EL (enhancement layer) serving as the upperlayer and the I picture, the B picture, and the B picture of the BL(base layer) serving as the lower layer are illustrated. The scalableHEVC means scalable video coding defined in the HEVC.

ex11 is an example in which all the pictures are decoded by the decodingdevice #0. On the other hand, ex12 is an example in which the lowerlayer of the I picture, the B picture, and the B picture of the BL isdecoded by the decoding device #0, and the upper layer of the I picture,the B picture, and the B picture of the EL is decoded by the decodingdevice #1.

For each layer of the scalable HEVC, each time layer of temporalscalability at the right side is configured as a sublayer.

As described above, in the temporal scalability of the related art, inthe scalable HEVC, a process may be performed by a single decodingdevice, and a parallel process may be performed by a plurality ofdecoding devices. Further, through the syntax of FIG. 5, it is possibleto designate the HRD parameter serving as the parameter used to managethe decoder buffer for each layer or a time layer that is one ofsublayers.

However, as illustrated in FIG. 6, it is difficult to detect whether thedecoding process is performed by a single decoding device or a pluralityof decoding devices.

In this regard, in the present technology, the HRD parameter istransmitted through syntax illustrated in FIG. 7. In other words, in thepresent technology, information indicating whether the HRD parameter isa parameter for performing a decoding process only in a correspondinglayer or a parameter for performing a decoding process of acorresponding layer and a lower layer is set. Thus, as illustrated inFIG. 6, it is clearly defined whether the decoding process is performedby a single decoding device or a plurality of decoding devices, and thusit is possible to perform a decoding process at a proper timing.

<Example of HRD Parameter>

FIG. 7 is a diagram illustrating an example of syntax of the HRDparameter according to the present technology. Numbers on the left ofeach row are row numbers added for description.

In an example of FIG. 7, hrd_parameters_type_flag is defined in a 10throw. When a value of hrd_parameters type_flag is 1, a value forperforming a decoding process of only a corresponding layer is set as anHRD parameter of a subsequent paragraph. When a value ofhrd_parameters_type_flag is 0, a value for performing a decoding processof a corresponding layer and a lower layer is set as an HRD parameter ofa subsequent paragraph.

Further, hrd_parameters_type_flag may be included in an if statementstarting from an 11th row.

sub_hrd_parameters_type[i]_flag is defined in a 25th row. When a valueof sub_hrd_parameters_type[i]_flag is 1, a value for performing adecoding process of only a corresponding time layer is set as a sub HRDparameter of a subsequent paragraph. When a value ofhrd_parameters_type_flag is 0, a value for performing a decoding processof a corresponding time layer and a lower time layer is set as a sub HRDparameter of a subsequent paragraph.

FIG. 7 illustrates the example in which the designating is performed byany one method (either only a corresponding layer is included or a lowerlayer is also included) for each layer and each time layer, but thepresent technology is not limited to this example. For example, the HRDparameter in which the HRD parameter is designated by both methods maybe included.

<Other Example of HRD Parameter>

FIG. 8 is a diagram illustrating another example of syntax of the HRDparameter according to the present technology. Numbers on the left ofeach row are row numbers added for description.

In an example of FIG. 8, hrd_parameters_type1_present_flag is defined inan 11th row. When a value of hrd_parameters_type1_present_flag is 1, avalue for performing a decoding process of only a corresponding layer isset as an HRD parameter of type1 set in 13th to 24th rows. When a valueof hrd_parameters_type1_present_flag is 0, a value for performing adecoding process of a corresponding layer and a lower layer is set asthe HRD parameter of type1.

hrd_parameters_type2_present_flag is defined in a 12th row. When a valueof hrd_parameters_type2_present_flag is 1, a value for performing adecoding process of only a corresponding layer is set as an HRDparameter of type2 defined in 25th to 36th rows. When a value ofhrd_parameters_type1_present_flag is 0, a value for performing adecoding process of a corresponding layer and a lower layer is set asthe HRD parameter of type2.

Similarly to the example described above with reference to FIG. 7, theflags of the 11th and 12th rows may be described before an if statementstarting from a 10th row.

sub_hrd_parameters_type1_present_flag is defined in a 40th row. When avalue of sub_hrd_parameters_type1_present_flag is 1, a value forperforming a decoding process of only a corresponding time layer is setas an HRD parameter of type set in 45th to 52nd rows. When a value ofsub_hrd_parameters_type1_present_flag is 0, a value for performing adecoding process of a corresponding time layer and a lower time layer isset as the HRD parameter of type1.

sub_hrd_parameters_type2_present_flag is defined in a 41st row. When avalue of sub_hrd_parameters_type2_present_flag is 1, a value forperforming a decoding process of only a corresponding time layer is setas an HRD parameter of type2 set in 53rd to 60th rows. When a value ofsub_hrd_parameters_type1_present_flag is 0, a value for performing adecoding process of a corresponding time layer and a lower time layer isset as an HRD parameter of type2.

As described above, in the present technology, the parameters of type1and type2 serving as the HRD parameter for the decoding process of onlythe corresponding layer and the HRD parameter for the decoding processof the corresponding layer and the lower layer are set at the encodingside. Thus, the decoding side can select the parameter according to adevice or a received bitstream.

Further, when the image compression information includes only one layer,that is, a scalability layer or a temporal scalability layer,hrd_parameter_type_flag and sub_hrd_parameter_type_flag may have anyvalue, and the decoding process is not affected.

Next, the present technology will be described in connection withapplications to a specific device. For the sake of convenience ofdescription, the following description will proceed with a case of ex12of the scalable HEVC and ex1 of temporal scalability in FIG. 6. Here,the present technology is not limited to this case. For example, theremay be a case of ex12 of the scalable HEVC and ex2 of temporalscalability in FIG. 6, a case of ex11 of the scalable HEVC and ex2 oftemporal scalability in FIG. 6, and a case of ex11 of the scalable HEVCand ex1 of temporal scalability in FIG. 6.

1. First Embodiment Scalable Encoding Device

FIG. 10 is a block diagram illustrating an example of a mainconfiguration of a scalable encoding device.

A scalable encoding device 100 illustrated in FIG. 10 encodes each layerof image data hierarchized into a base layer and an enhancement layer.

The scalable encoding device 100 is configured to include a base layerimage encoding section 101-1, an enhancement layer image encodingsection 101-2, and an encoding control section 102.

The base layer image encoding section 101-1 acquires image information(base layer image information) of the base layer. The base layer imageencoding section 101-1 encodes the base layer image information withoutreferring to other layers, generates encoded data (base layer encodeddata) of the base layer, and outputs the generated encoded data.

The enhancement layer image encoding section 101-2 acquires imageinformation (enhancement layer image information) of the enhancementlayer. The enhancement layer image encoding section 101-2 encodes theenhancement layer image information. At this time, the enhancement layerimage encoding section 101-2 performs inter-layer prediction withreference to information related to encoding of the base layer asnecessary.

Further, the enhancement layer image encoding section 101-2 sets the HRDparameter type for each layer, and calculates the HRD parameter servingas the parameter used to manage the decoder buffer based on stateinformation of an accumulation buffer according to the set HRD parametertype. The enhancement layer image encoding section 101-2 encodes thecalculated HRD parameter.

Specifically, the HRD parameter type indicates whether the HRD parameteris the parameter for decoding only a corresponding layer or theparameter for performing the decoding process of a corresponding layerand a lower layer. This type may set both of the parameters as well asany one of the parameters. The encoding side calculates the HRDparameter according to the flag (information) indicating the set type,and transmits the flag indicating the set type and the calculated HRDparameter to the decoding side. Hereinafter, the flag indicating the HRDparameter type is appropriately referred to as an “HRD parameter typeflag.”

When the flag indicating the HRD parameter type is 1, the enhancementlayer image encoding section 101-2 calculates the HRD parameter based onthe state information of its own accumulation buffer. When the flagindicating the HRD parameter type is 0, the enhancement layer imageencoding section 101-2 acquires state information of the wholeaccumulation buffer of the base layer image encoding section 101-1, andcalculates the HRD parameter based on the state information of the baselayer image encoding section 101-1 and its own accumulation buffer. Thisprocess is performed on a layer and a sublayer (time layer). In the baselayer image encoding section 101-1, this process is performed only onthe sublayer.

The enhancement layer image encoding section 101-2 generates encodeddata (enhancement layer encoded data) of the enhancement layer throughthe above encoding, and outputs the generated encoded data.

The base layer image encoding section 101-1 and the enhancement layerimage encoding section 101-2 are appropriately referred to collectivelyas a “layer image encoding section 101.”

The encoding control section 102 controls the encoding process of thelayer image encoding sections 101, for example, in view of the referencerelation of the layer image encoding sections 101.

In the example of FIG. 10, one enhancement layer image encoding section101-2 is illustrated, but when there is an upper layer, enhancementlayer image encoding sections 101-3, 101-4, . . . that encode the upperlayer are provided for each of the upper layers.

<Example of Configuration of Layer Image Encoding Section>

FIG. 11 is a block diagram illustrating an example of a mainconfiguration of the enhancement layer image encoding section 101-2. Thebase layer image encoding section 101-1 of FIG. 10 has basically thesame configuration as the enhancement layer image encoding section 101-2of FIG. 11 except that a type of an image serving as a target isdifferent. For the sake of convenience of description, in the example ofFIG. 11, a configuration of the enhancement layer image encoding section101-2 will be described as an example.

As illustrated in FIG. 11, the enhancement layer image encoding section101-2 includes an A/D converting section 111, a screen reordering buffer112, an operation section 113, an orthogonal transform section 114, aquantization section 115, a lossless encoding section 116, anaccumulation buffer 117, an inverse quantization section 118, and aninverse orthogonal transform section 119. The enhancement layer imageencoding section 101-2 further includes an operation section 120, a loopfilter 121, a frame memory 122, a selecting section 123, an intraprediction section 124, a motion prediction/compensation section 125, apredictive image selecting section 126, and a rate control section 127.The enhancement layer image encoding section 101-2 further includes anHRD type setting section 128.

The A/D converting section 111 performs A/D conversion on input imagedata (the enhancement layer image information), and supplies theconverted image data (digital data) to be stored in the screenreordering buffer 112. The screen reordering buffer 112 reorders imagesof frames stored in a display order in a frame order for encodingaccording to a Group Of Pictures (GOP), and supplies the images in whichthe frame order is reordered to the operation section 113. The screenreordering buffer 112 also supplies the images in which the frame orderis reordered to the intra prediction section 124 and the motionprediction/compensation section 125.

The operation section 113 subtracts a predictive image supplied from theintra prediction section 124 or the motion prediction/compensationsection 125 via the predictive image selecting section 126 from an imageread from the screen reordering buffer 112, and outputs differentialinformation thereof to the orthogonal transform section 114. Forexample, in the case of an image that has been subjected to intracoding, the operation section 113 subtracts the predictive imagesupplied from the intra prediction section 124 from the image read fromthe screen reordering buffer 112. Further, for example, in the case ofan image that has been subjected to inter coding, the operation section113 subtracts the predictive image supplied from the motionprediction/compensation section 125 from the image read from the screenreordering buffer 112.

The orthogonal transform section 114 performs an orthogonal transformsuch as a discrete cosine transform or a Karhunen-Loève Transform on thedifferential information supplied from the operation section 113. Theorthogonal transform section 114 supplies transform coefficients to thequantization section 115.

The quantization section 115 quantizes the transform coefficientssupplied from the orthogonal transform section 114. The quantizationsection 115 sets a quantization parameter based on information relatedto a target value of a coding amount supplied from the rate controlsection 127, and performs the quantizing. The quantization section 115supplies the quantized transform coefficients to the lossless encodingsection 116.

The lossless encoding section 116 encodes the transform coefficientsquantized in the quantization section 115 according to an arbitraryencoding scheme. Since coefficient data is quantized under control ofthe rate control section 127, the coding amount becomes a target value(or approaches a target value) set by the rate control section 127.

The lossless encoding section 116 acquires information indicating anintra prediction mode or the like from the intra prediction section 124,and acquires information indicating an inter prediction mode,differential motion vector information, or the like from the motionprediction/compensation section 125. Further, the lossless encodingsection 116 appropriately generates an NAL unit of the enhancement layerincluding a sequence parameter set (SPS), a picture parameter set (PPS),and the like.

The lossless encoding section 116 encodes various kinds of informationaccording to an arbitrary encoding scheme, and sets (multiplexes) theencoded information as part of encoded data (also referred to as an“encoded stream”). The lossless encoding section 116 supplies theencoded data obtained by the encoding to be accumulated in theaccumulation buffer 117.

Examples of the encoding scheme of the lossless encoding section 116include variable length coding and arithmetic coding. As the variablelength coding, for example, there is Context-Adaptive Variable LengthCoding (CAVLC) defined in the H.264/AVC scheme. As the arithmeticcoding, for example, there is Context-Adaptive Binary Arithmetic Coding(CABAC).

The accumulation buffer 117 temporarily holds the encoded data(enhancement layer encoded data) supplied from the lossless encodingsection 116. The accumulation buffer 117 outputs the held enhancementlayer encoded data to a recording device (recording medium), atransmission path, or the like (not illustrated) at a subsequent stageat a certain timing. In other words, the accumulation buffer 117 servesas a transmitting section that transmits the encoded data as well.Further, when there is a request from the HRD type setting section 128,the accumulation buffer 117 supplies information indicating a state ofthe accumulation buffer 117. Further, for example, when there is anenhancement layer image encoding section 101-3 of an upper layer, andthere is a request from its HRD type setting section 128 as indicated bya dotted line, the accumulation buffer 117 supplies the informationindicating the state of the accumulation buffer 117 to the enhancementlayer image encoding section 101-3 of the upper layer.

The transform coefficients quantized by the quantization section 115 arealso supplied to the inverse quantization section 118. The inversequantization section 118 inversely quantizes the quantized transformcoefficients according to a method corresponding to the quantizationperformed by the quantization section 115. The inverse quantizationsection 118 supplies the obtained transform coefficients to the inverseorthogonal transform section 119.

The inverse orthogonal transform section 119 performs an inverseorthogonal transform on the transform coefficients supplied from theinverse quantization section 118 according to a method corresponding tothe orthogonal transform process performed by the orthogonal transformsection 114. An output (restored differential information) that has beensubjected to the inverse orthogonal transform is supplied to theoperation section 120.

The operation section 120 obtains a locally decoded image (a decodedimage) by adding the predictive image supplied from the intra predictionsection 124 or the motion prediction/compensation section 125 via thepredictive image selecting section 126 to the restored differentialinformation serving as an inverse orthogonal transform result suppliedfrom the inverse orthogonal transform section 119. The decoded image issupplied to the loop filter 121 or the frame memory 122.

The loop filter 121 includes a deblock filter, an adaptive offsetfilter, an adaptive loop filter, or the like, and appropriately performsa filter process on the reconstructed image supplied from the operationsection 120. For example, the loop filter 121 performs the deblockfilter process on the reconstructed image, and removes block distortionof the reconstructed image. Further, for example, the loop filter 121improves the image quality by performing the loop filter process on thedeblock filter process result (the reconstructed image from which theblock distortion has been removed) using a Wiener filter. The loopfilter 121 supplies the filter process result (hereinafter referred toas a “decoded image”) to the frame memory 122.

The loop filter 121 may further perform any other arbitrary filterprocess on the reconstructed image. The loop filter 121 may supplyinformation used in the filter process such as a filter coefficient tothe lossless encoding section 116 as necessary so that the informationcan be encoded.

The frame memory 122 stores the reconstructed image supplied from theoperation section 120 and the decoded image supplied from the loopfilter 121. The frame memory 122 supplies the stored reconstructed imageto the intra prediction section 124 via the selecting section 123 at acertain timing or based on an external request, for example, from theintra prediction section 124. Further, the frame memory 122 supplies thestored decoded image to the motion prediction/compensation section 125via the selecting section 123 at a certain timing or based on anexternal request, for example, from the motion prediction/compensationsection 125.

The frame memory 122 stores the supplied decoded image, and supplies thestored decoded image to the selecting section 123 as a reference imageat a certain timing.

The selecting section 123 selects a supply destination of the referenceimage supplied from the frame memory 122. For example, in the case ofthe intra prediction, the selecting section 123 supplies the referenceimage (a pixel value of a current picture) supplied from the framememory 122 to the motion prediction/compensation section 125. Further,for example, in the case of the inter prediction, the selecting section123 supplies the reference image supplied from the frame memory 122 tothe motion prediction/compensation section 125.

The intra prediction section 124 performs the intra prediction(intra-screen prediction) for generating the predictive image using thepixel value of the current picture serving as the reference imagesupplied from the frame memory 122 via the selecting section 123. Theintra prediction section 124 performs the intra prediction in aplurality of intra prediction modes that are prepared in advance.

The intra prediction section 124 generates predictive images in all theintra prediction modes serving as the candidates, evaluates costfunction values of the predictive images using the input image suppliedfrom the screen reordering buffer 112, and selects an optimal mode. Whenthe optimal intra prediction mode is selected, the intra predictionsection 124 supplies the predictive image generated in the optimal modeto the predictive image selecting section 126.

As described above, the intra prediction section 124 appropriatelysupplies, for example, the intra prediction mode information indicatingthe employed intra prediction mode to the lossless encoding section 116so that the information is encoded.

The motion prediction/compensation section 125 performs the motionprediction (the inter prediction) using the input image supplied fromthe screen reordering buffer 112 and the reference image supplied fromthe frame memory 122 via the selecting section 123. Although notillustrated, in the motion prediction/compensation section 125, thereference image supplied from the frame memory 122 of the base layerimage encoding section 101-1 is also referred to as necessary. Themotion prediction/compensation section 125 performs a motioncompensation process according to a detected motion vector, andgenerates a predictive image (inter-predictive image information). Themotion prediction/compensation section 125 performs the inter predictionin a plurality of inter prediction modes that are prepared in advance.

The motion prediction/compensation section 125 generates predictiveimages in all the inter prediction modes serving as a candidate. Themotion prediction/compensation section 125 evaluates cost functionvalues of the predictive images using the input image supplied from thescreen reordering buffer 112, information of the generated differentialmotion vector, and the like, and selects an optimal mode. When theoptimal inter prediction mode is selected, the motionprediction/compensation section 125 supplies the predictive imagegenerated in the optimal mode to the predictive image selecting section126.

The motion prediction/compensation section 125 supplies informationindicating the employed inter prediction mode, information necessary forperforming processing in the inter prediction mode when the encoded datais decoded, and the like to the lossless encoding section 116 so thatthe information is encoded. For example, as the necessary information,there is information of a generated differential motion vector, and asprediction motion vector information, there is a flag indicating anindex of a prediction motion vector.

The predictive image selecting section 126 selects a supply source ofthe prediction image to be supplied to the operation section 113 and theoperation section 120. For example, in the case of the intra coding, thepredictive image selecting section 126 selects the intra predictionsection 124 as the supply source of the predictive image, and suppliesthe predictive image supplied from the intra prediction section 124 tothe operation section 113 and the operation section 120. For example, inthe case of the inter coding, the predictive image selecting section 126selects the motion prediction/compensation section 125 as the supplysource of the predictive image, and supplies the predictive imagesupplied from the motion prediction/compensation section 125 to theoperation section 113 and the operation section 120.

The rate control section 127 controls a rate of a quantization operationof the quantization section 115 based on the coding amount of theencoded data accumulated in the accumulation buffer 117 such that nooverflow or underflow occurs.

The HRD type setting section 128 decides the HRD parameter typeaccording to the user's instruction, and acquires information indicatingan accumulation state from the accumulation buffer 117 or theaccumulation buffer (the lower layer) 117 of the base layer imageencoding section 101-1 according to the decided HRD parameter type. TheHRD type setting section 128 calculates the HRD parameter based on theacquired information, and causes the lossless encoding section 116 toencode the flag indicating the HRD parameter type and the HRD parameter.

Further, when the image compression information (encoded data) to beoutput includes one layer, the value of the flag indicating the HRDparameter type is arbitrary, and does not affect the process at thedecoding side.

<Example of Configuration of Accumulation Buffer and HRD Type SettingSection>

FIG. 12 is a block diagram illustrating an example of a configuration ofthe accumulation buffer and the HRD type setting section of FIG. 11.

In an example of FIG. 12, the accumulation buffer 117 is configured toinclude a partial accumulation buffer 131 and a whole accumulationbuffer 132.

The HRD type setting section 128 is configured to include a layer HRDparameter calculating section 141, a time layer HRD parametercalculating section 142, an HRD parameter type setting section 143, anda time HRD parameter type setting section 144.

The partial accumulation buffer 131 is configured with each accumulationbuffer that accumulates encoded data related to each upper time layeramong the encoded data (codes) accumulated in the whole accumulationbuffer 132. The information indicating the state of each accumulationbuffer is supplied to the time layer HRD parameter calculating section142 on request.

The whole accumulation buffer 132 accumulates the encoded data (codes)encoded by the lossless encoding section 116. Further, informationindicating a state of the whole accumulation buffer of the wholeaccumulation buffer 132 is supplied to the layer HRD parametercalculating section 141 and the time layer HRD parameter calculatingsection 142 on request. Further, there are cases in which there is theenhancement layer image encoding section 101-3 of the upper layer asindicated by a dotted line. In this case, the information indicating thestate of the whole accumulation buffer of the whole accumulation buffer132 is also supplied to the HRD type setting section (upper layer) 128according to the request of the HRD type setting section (upper layer)128 of the enhancement layer image encoding section 101-3.

The layer HRD parameter calculating section 141 acquires the informationindicating the state of the whole accumulation buffer 132 and theinformation indicating the state of the accumulation buffer (the lowerlayer) 117 of the base layer image encoding section 101-1 according tothe HRD parameter type (flag) supplied from the HRD parameter typesetting section 143. Practically, information is acquired from the wholeaccumulation buffer 132 of the accumulation buffer of the base layerimage encoding section 101-1.

When the HRD parameter type flag indicates 1, the information indicatingthe state of the whole accumulation buffer 132 is acquired. When the HRDparameter type flag indicates 0, the information indicating the state ofthe whole accumulation buffer 132 and the information indicating thestate of the accumulation buffer (the lower layer) 117 of the base layerimage encoding section 101-1 are acquired.

The layer HRD parameter calculating section 141 calculates a layer HRDparameter based on the HRD parameter type flag supplied from the HRDparameter type setting section 143 and the acquired information, andsupplies the calculated layer HRD parameter to the lossless encodingsection 116.

The time layer HRD parameter calculating section 142 acquires theinformation indicating the state of the whole accumulation buffer 132and the information indicating the state of the accumulation buffer ofthe corresponding time layer of the partial accumulation buffer 131according to the sub HRD parameter type (flag) supplied from the timeHRD parameter type setting section 144.

When the sub HRD parameter type flag indicates 1, the informationindicating the state of the accumulation buffer of the correspondingtime layer of the partial accumulation buffer 131 is acquired. When thesub HRD parameter type flag indicates 0, the information indicating thestate of the whole accumulation buffer 132 and the informationindicating the state of the accumulation buffer of the correspondingtime layer of the partial accumulation buffer 131 are acquired.

The time layer HRD parameter calculating section 142 calculates a timelayer HRD parameter based on the sub HRD parameter type supplied fromthe time HRD parameter type setting section 144 and the acquiredinformation, and supplies the calculated time layer HRD parameter to thelossless encoding section 116.

The HRD parameter type setting section 143 sets the HRD parameter typeaccording to the user's instruction, and supplies the flag indicatingthe set HRD parameter type to the lossless encoding section 116 and thelayer HRD parameter calculating section 141.

The time HRD parameter type setting section 144 sets the sub HRDparameter type according to the user's instruction, and supplies a flagindicating the set sub HRD parameter type to the lossless encodingsection 116 and the time layer HRD parameter calculating section 142.

The lossless encoding section 116 encodes the flag indicating the HRDparameter type supplied from the HRD parameter type setting section 143and the layer HRD parameter supplied from the layer HRD parametercalculating section 141, and sets the encoded information as headerinformation of the encoded data. The lossless encoding section 116encodes the flag indicating the sub HRD parameter type supplied from thetime HRD parameter type setting section 144, and the time layer HRDparameter supplied from the time layer HRD parameter calculating section142, and sets the encoded information as the header information of theencoded data. The encoded data is output to the whole accumulationbuffer 132.

<Layer Structure>

In the scalable video coding, image data is hierarchized into aplurality of layers as described above with reference to FIGS. 2 to 4.In the following, for the sake of description, this layer is referred toas a main layer.

A picture group of each main layer configures a sequence in the mainlayer. The pictures in the sequence form a hierarchical structure (a GOPstructure) as illustrated in FIG. 13, similarly to moving image data ofa single main layer. In the following, for the sake of description, alayer in one main layer is referred to as a sublayer.

In the example of FIG. 13, a main layer is configured with two layers,that is, a base layer (BaseLayer) and an enhancement layer (EnhLayer).The base layer is a layer in which an image is formed by only its ownmain layer without depending on other main layers. Data of the baselayer is encoded and decoded without referring to other main layers. Theenhancement layer is a main layer that is combined with data of the baselayer to obtain an image. Data of the enhancement layer can be used by aprediction process (an inter-main layer prediction process) (which isalso referred to as “inter-layer prediction”) with a corresponding baselayer.

The number of main layers of encoded data hierarchized by the scalablevideo coding is arbitrary. In the following, each main layer is assumedto be set as a base layer or an enhancement layer, and in eachenhancement layer, any one base layer is assumed to be set as areference destination.

In the example of FIG. 13, each of the base layer and the enhancementlayer has a GOP structure configured with three sublayers, that is, asublayer 0 (Sublayer0), a sublayer 1 (Sublayer1), and a sublayer 2(Sublayer2). A square illustrated in FIG. 13 indicates a picture, and acharacter in the square indicates a type of a picture. For example, asquare in which “I” is written indicates an I picture, a square in which“B” is written indicates a B picture that is referable to, and a squarein which “b” is written indicates a B picture that is not referred to.Further, a dotted line between squares indicates a dependence relation(a reference relation). As indicated by individual dotted lines, apicture of an upper sublayer depends on a picture of a lower sublayer.In other words, the picture of the sublayer 1 or the picture of thesublayer 0 is referred to by the picture of the sublayer 2 (Sublayer2).Further, the picture of the sublayer 0 is referred to by the picture ofthe sublayer 1. The picture of the sublayer 0 is appropriately referredto by the picture of the sublayer 0.

The number of sublayers (a sublayer number) is arbitrary. The GOPstructure is also arbitrary, and not limited to the example of FIG. 13.

Here, a correspondence relation with the present embodiment will bedescribed. Encoded data of all pictures of the enhancement layer isaccumulated in the whole accumulation buffer 132 of FIG. 12.

The partial accumulation buffer 131 of FIG. 12 includes an accumulationbuffer of the sublayer 1 and an accumulation buffer of the sublayer 2.In other words, for example, encoded data of the B pictures of thesublayer 1 indicated by B2, B4, and B6 in the enhancement layer of FIG.13 is accumulated in the accumulation buffer of the sublayer 1. Encodeddata of the B pictures of the sublayer 2 indicated by b1, b3, b5, and b7in the enhancement layer is accumulated in the accumulation buffer ofthe sublayer 2.

Further, encoded data of all pictures of the base layer of FIG. 13 isaccumulated in (the whole accumulation buffer 132 of) the accumulationbuffer 117 of the base layer image encoding section 101-1 illustrated inFIG. 12, and information indicating the buffer state is supplied to thelayer HRD parameter calculating section 141 as information indicating astate of the lower layer whole accumulation buffer.

Further, although not illustrated, the partial accumulation buffer 131of the accumulation buffer 117 of the base layer image encoding section101-1 includes an accumulation buffer of the sublayer 1 and anaccumulation buffer of the sublayer 2. In other words, for example,encoded data of the B pictures of the sublayer 1 indicated by B2, B4,and B6 in the base layer of FIG. 13 is accumulated in the accumulationbuffer of the sublayer 1. Encoded data of the B pictures of the sublayer2 indicated by b1, b3, b5, and b7 in the base layer is accumulated inthe accumulation buffer of the sublayer 2.

<Flow of Encoding Process>

Next, the flow of the process performed by the scalable encoding device100 will be described. First, an example of the flow of an encodingprocess will be described with reference to a flowchart of FIG. 14.

When the encoding process starts, in step S101, the encoding controlsection 102 of the scalable encoding device 100 decides a layer of aprocessing target in view of the reference relation of an image or thelike.

In step S102, the base layer image encoding section 101-1 performs alayer encoding process under control of the encoding control section102. The layer encoding process will be described later with referenceto FIG. 15. When the process of step S102 ends, the process proceeds tostep S103.

In step S103, the encoding control section 102 determines whether or notall the main layers have been processed. When it is determined thatthere is a non-processed main layer, the process proceeds to step S104.

In step S104, the encoding control section 102 sets a next non-processedmain layer as a processing target (current main layer). When the processof step S104 ends, the process returns to step S102. In step S102, theenhancement layer image encoding section 101-2 performs the layerencoding process under control of the encoding control section 102. Theprocess of steps S102 to S104 is repeatedly performed to encode the mainlayers as described above. The process of step S102 may be processed inparallel by a plurality of layer image encoding sections 101 having noreference relation.

Then, when all the main layers are determined to have been processed instep S103, the encoding process ends.

<Flow of Layer Encoding Process>

Next, the layer encoding process in step S102 of FIG. 14 will bedescribed with reference to a flowchart of FIG. 15. An example of FIG.15 will be described in connection with an example of the enhancementlayer image encoding section 101-2.

In step Sill, the A/D converting section 111 of the enhancement layerimage encoding section 101-2 performs A/D conversion on input imageinformation (image data) of the enhancement layer. In step S112, thescreen reordering buffer 112 stores image information (digital data) ofthe enhancement layer that has been subjected to the A/D conversion, andreorders the pictures arranged in the display order in the encodingorder.

In step S113, the intra prediction section 124 performs the intraprediction process in the intra prediction mode. In step S114, themotion prediction/compensation section 125 performs an inter motionprediction process in which motion prediction and motion compensation inthe inter prediction mode are performed. In step S115, the predictiveimage selecting section 126 decides an optimal mode based on the costfunction values output from the intra prediction section 124 and themotion prediction/compensation section 125. In other words, thepredictive image selecting section 126 selects either of the predictiveimage generated by the intra prediction section 124 and the predictiveimage generated by the motion prediction/compensation section 125. Instep S116, the operation section 113 calculates a difference between theimage reordered in the process of step S112 and the predictive imageselected in the process of step S115. The differential data is smallerin a data amount than the original image data. Thus, it is possible tocompress a data amount to be smaller than when an image is encodedwithout change.

In step S117, the orthogonal transform section 114 performs theorthogonal transform process on the differential information generatedin the process of step S116. In step S118, the quantization section 115quantizes the orthogonal transform coefficients obtained in the processof step S117 using the quantization parameter calculated by the ratecontrol section 127.

The differential information quantized in the process of step S118 islocally decoded as follows. In other words, in step S119, the inversequantization section 118 performs inverse quantization on the quantizedcoefficients (which are also referred to as “quantization coefficients”)quantized in the process of step S118 according to characteristicscorresponding to characteristics of the quantization section 115. Instep S120, the inverse orthogonal transform section 119 performs theinverse orthogonal transform on the orthogonal transform coefficientsobtained in the process of step S117. In step S121, the operationsection 120 generates a locally decoded image (an image corresponding toan input of the operation section 113) by adding the predictive image tothe locally decoded differential information.

In step S122, the loop filter 121 performs filtering on the imagegenerated in the process of step S121. As a result, for example, blockdistortion is removed. In step S123, the frame memory 122 stores theimage in which, for example, the block distortion has been deleted inthe process of step S122. The image that is not subjected to the filterprocess performed by the loop filter 121 is also supplied from theoperation section 120 and stored in the frame memory 122. The imagestored in the frame memory 122 is used in the process of step S113 orthe process of step S114.

In step S124, the HRD type setting section 128 performs an HRD parameterencoding process. The HRD parameter encoding process will be describedlater with reference to FIG. 16, and through this process, the flagindicating the HRD parameter type and the HRD parameter are supplied tothe lossless encoding section 116.

In step S125, the lossless encoding section 116 encodes the coefficientsquantized in the process of step S118. In other words, lossless codingsuch as variable length coding or arithmetic coding is performed on datacorresponding to the differential image.

At this time, the lossless encoding section 116 encodes informationrelated to the prediction mode of the predictive image selected in theprocess of step SI 15, and adds the encoded information to the encodeddata obtained by encoding the differential image. In other words, thelossless encoding section 116 also encodes, for example, informationaccording to the optimal intra prediction mode information supplied fromthe intra prediction section 124 or the optimal inter prediction modesupplied from the motion prediction/compensation section 125, and addsthe encoded information to the encoded data. Further, the losslessencoding section 116 also encodes information such as a flag indicatingthe HRD parameter type and the HRD parameter supplied in the process ofstep S124, and adds the encoded information to the encoded data.

In step S126, the accumulation buffer 117 accumulates the enhancementlayer encoded data obtained in the process of step S125. The enhancementlayer encoded data accumulated in the accumulation buffer 117 isappropriately read and transmitted to the decoding side via atransmission path or a recording medium.

In step S127, the rate control section 127 controls the quantizationoperation of the quantization section 115 based on the coding amount(the generated coding amount) of the encoded data accumulated in theaccumulation buffer 117 in the process of step S126 so that no overflowor underflow occurs. Further, the rate control section 127 suppliesinformation related to the quantization parameter to the quantizationsection 115.

When the process of step S127 ends, the encoding process ends, and theprocess returns to step S102 of FIG. 14.

<Flow of HRD Parameter Encoding Process>

Next, an example of encoding the HRD parameter illustrated in FIG. 7will be described with reference to a flowchart of FIG. 16.

In step S131, the HRD parameter type setting section 143 sets the HRDparameter type according to the user's instruction. The HRD parametertype setting section 143 supplies the flag indicating the set HRDparameter type to the lossless encoding section 116 and the layer HRDparameter calculating section 141.

In step S132, the layer HRD parameter calculating section 141 performs aprocess of calculating the HRD parameter of the corresponding layeraccording to the flag indicating the HRD parameter type supplied fromthe HRD parameter type setting section 143. The process of calculatingthe HRD parameter will be described later with reference to FIG. 17.

In step S133, the layer HRD parameter calculating section 141 suppliesthe HRD parameter of the corresponding layer calculated in step S132 tothe lossless encoding section 116 so that the HRD parameter of thecorresponding layer is encoded.

The flag indicating the HRD parameter type supplied in step S131 and theHRD parameter of the layer supplied in step S133 are encoded in stepS125 of FIG. 15.

In step S134, the time HRD parameter type setting section 144 sets thesub HRD parameter type according to the user's instruction. The time HRDparameter type setting section 144 supplies the flag indicating the setsub HRD parameter type to the lossless encoding section 116 and the timelayer HRD parameter calculating section 142.

In step S135, the time layer HRD parameter calculating section 142performs a process of calculating the HRD parameter of the correspondingtime layer according to the flag indicating the sub HRD parameter typesupplied from the time HRD parameter type setting section 144. Theprocess of calculating the HRD parameter of the time layer will bedescribed later with reference to FIG. 18.

In step S136, the time layer HRD parameter calculating section 142supplies the HRD parameter of the time layer calculated in step S135 tothe lossless encoding section 116 so that the HRD parameter of the timelayer is encoded.

The flag indicating the sub HRD parameter type supplied in step S134 andthe HRD parameter of the time layer supplied in step S134 are encoded instep S125 of FIG. 15.

In step S137, the time layer HRD parameter calculating section 142determines whether or not the process has ended on all the time layers.When the process is determined to have ended on all the time layers instep S137, the HRD parameter encoding process ends, and the processreturns to step S124 of FIG. 15.

When the process is determined not to have ended on any one of the timelayers in step S137, the process returns to step S134, and thesubsequent process is repeated.

<Flow of HRD Parameter Calculation Process>

Next, the process of calculating the HRD parameter in step S132 of FIG.16 will be described with reference to a flowchart of FIG. 17.

The HRD parameter type flag is supplied to the layer HRD parametercalculating section 141 through step S131 of FIG. 16. In step S141, thelayer HRD parameter calculating section 141 determines whether or notthe HRD parameter type flag supplied from the HRD parameter type settingsection 143 is 1.

When the HRD parameter type flag is determined to be 1 in step S141, theprocess proceeds to step S142.

In step S142, the layer HRD parameter calculating section 141 acquiresthe information indicating the state of the whole accumulation buffer132. In step S143, the layer HRD parameter calculating section 141calculates the HRD parameter of the corresponding layer based on theacquired information indicating the state of the whole accumulationbuffer 132.

When the HRD parameter type flag is determined not to be 1 in step S141,the process proceeds to step S144.

In step S144, the layer HRD parameter calculating section 141 acquiresthe information indicating the state of the whole accumulation buffer132. In step S145, the layer HRD parameter calculating section 141acquires the information indicating the state of the accumulation buffer(the lower layer) 117 of the base layer image encoding section 101-1. Instep S146, the layer HRD parameter calculating section 141 calculatesthe HRD parameter of the corresponding layer based on the acquiredinformation.

After step S143 or S146, the HRD parameter calculation process ends, andthe process returns to step S132 of FIG. 16.

<Flow of Time Layer HRD Parameter Calculation Process>

Next, the process of calculating the HRD parameter of the time layer instep S135 of FIG. 16 will be described with reference to a flowchart ofFIG. 18.

The sub HRD parameter type flag is supplied to the time layer HRDparameter calculating section 142 through step S134 of FIG. 16. In stepS151, the time layer HRD parameter calculating section 142 determineswhether or not the sub HRD parameter type flag supplied from the timeHRD parameter type setting section 144 is 1.

When the sub HRD parameter type flag is determined to be 1 in step S151,the process proceeds to step S152.

In step S152, the time layer HRD parameter calculating section 142acquires the information indicating the state of the accumulation bufferof the corresponding time layer of the partial accumulation buffer 131.In step S153, the time layer HRD parameter calculating section 142calculates the HRD parameter of the time layer based on the acquiredinformation indicating the state of the partial accumulation buffer 131.

When the sub HRD parameter type flag is determined not to be 1 in stepS151, the process proceeds to step S154.

In step S154, the time layer HRD parameter calculating section 142acquires the information indicating the state of the whole accumulationbuffer 132. In step S155, the time layer HRD parameter calculatingsection 142 acquires the information indicating the state of theaccumulation buffer of the corresponding time layer of the partialaccumulation buffer 131. In step S156, the time layer HRD parametercalculating section 142 calculates the HRD parameter of thecorresponding time layer based on the acquired information.

After step S153 or S156, the time layer HRD parameter calculationprocess ends, and the process returns to step S135 of FIG. 16.

<Other Flow of HRD Parameter Encoding Process>

Next, the HRD parameter encoding process of step S124 of FIG. 15 will bedescribed with reference to a flowchart of FIG. 19. FIG. 16 illustratesan example of encoding the HRD parameter illustrated in FIGS. 8 and 9.

In step S161, the HRD parameter type setting section 143 sets the HRDparameter type according to the user's instruction. The HRD parametertype setting section 143 supplies the flag indicating the set HRDparameter type to the lossless encoding section 116 and the layer HRDparameter calculating section 141.

In step S162, the layer HRD parameter calculating section 141 performsthe process of calculating the HRD parameter of the corresponding layeraccording to the flag indicating the HRD parameter type supplied fromthe HRD parameter type setting section 143. Since the process ofcalculating the HRD parameter is basically the same as the processdescribed with reference to FIG. 17, duplicate description is omitted.

In step S163, the layer HRD parameter calculating section 141 determineswhether or not the HRD parameter calculation process has ended on bothof type1 and type2. When the HRD parameter calculation process isdetermined not to have ended on either type in step S163, the processreturns to step S162, and the subsequent process is repeated.

Further, when either of type1 and type2 is calculated, the processproceeds to step S163.

When the HRD parameter calculation process is determined to have endedon both type1 and type2 in step S163, the process proceeds to step S164.

In step S164, the layer HRD parameter calculating section 141 suppliesthe HRD parameter of the corresponding layer calculated in step S162 tothe lossless encoding section 116 so that the HRD parameter of thecorresponding layer is encoded.

The flag indicating the HRD parameter type supplied in step S161 and theHRD parameter of the layer supplied in step S164 are encoded in stepS125 of FIG. 15.

In step S165, the time HRD parameter type setting section 144 sets thesub HRD parameter type according to the user's instruction. The time HRDparameter type setting section 144 supplies the flag indicating the setsub HRD parameter type to the lossless encoding section 116 and the timelayer HRD parameter calculating section 142.

In step S166, the time layer HRD parameter calculating section 142performs the process of calculating the HRD parameter of thecorresponding time layer according to the flag indicating the sub HRDparameter type supplied from the time HRD parameter type setting section144. Since the process of calculating the HRD parameter of the timelayer is basically the same as the process described with reference toFIG. 18, duplicate description is omitted.

In step S167, the layer HRD parameter calculating section 141 determineswhether or not the HRD parameter calculation process has ended on bothof type1 and type2. When the HRD parameter calculation process isdetermined not to have ended on either type in step S163, the processreturns to step S166, and the subsequent process is repeated.

Further, when either of type1 and type2 is calculated, the processproceeds to step S168.

When the HRD parameter calculation process is determined to have endedon both type1 and type2 in step S167, the process proceeds to step S168.

In step S168, the time layer HRD parameter calculating section 142supplies the HRD parameter of the corresponding time layer calculated instep S166 to the lossless encoding section 116 so that the HRD parameterof the time layer is encoded.

The flag indicating the sub HRD parameter type supplied in step S165 andthe HRD parameter of the time layer supplied in step S168 are encoded instep S125 of FIG. 15.

In step S169, the time layer HRD parameter calculating section 142determines whether or not the process has ended on all the time layers.When the process is determined to have ended on all the time layers instep S169, the HRD parameter encoding process ends, and the processreturns to step S124 of FIG. 15.

When the process is determined not to have ended on any one of the timelayers in step S169, the process returns to step S165, and thesubsequent process is repeated.

As described above, the HRD parameter type flag indicating whether theHRD parameter is the parameter for performing the decoding process ofonly a corresponding layer or the parameter for performing the decodingprocess of the corresponding layer and the lower layer is set at theencoding side. Thus, it is possible to perform a decoding process at aproper timing.

2. Second Embodiment Scalable Decoding Device

Next, decoding of the encoded data (bitstream) that has been subjectedto the scalable video coding as described above will be described. FIG.20 is a block diagram illustrating an example of a main configuration ofa scalable decoding device corresponding to the scalable encoding device100 of FIG. 10. For example, a scalable decoding device 200 illustratedin FIG. 20 performs scalable decoding on the encoded data obtained byperforming the scalable encoding on the image data through the scalableencoding device 100 according to a method corresponding to the encodingmethod.

The scalable decoding device 200 is configured to include a base layerimage decoding section 201-1, an enhancement layer image decodingsection 201-2, and a decoding control section 202.

The base layer image decoding section 201-1 is an image decoding sectioncorresponding to the base layer image encoding section 101-1 of FIG. 10,and acquires, for example, the base layer encoded data obtained byencoding the base layer image information through the base layer imageencoding section 101-1. The base layer image decoding section 201-1decodes the base layer encoded data without referring to other layers,reconstructs the base layer image information, and outputs the baselayer image information.

The enhancement layer image decoding section 201-2 is an image decodingsection corresponding to the enhancement layer image encoding section101-2, and acquires, for example, the enhancement layer encoded dataobtained by encoding the enhancement layer image information through theenhancement layer image encoding section 101-2. The enhancement layerimage decoding section 201-2 decodes the enhancement layer encoded data.At this time, the enhancement layer image decoding section 201-2performs the inter-layer prediction with reference to informationrelated to decoding of the base layer as necessary.

Further, the flag indicating the HRD parameter type and the HRDparameter are added to each piece of encoded data (bitstream) andtransmitted. The enhancement layer image decoding section 201-2 receivesthe flag indicating the HRD parameter type, acquires the stateinformation of the accumulation buffer according to the received flagindicating the HRD parameter type, and monitors the accumulation buffer.

When the flag indicating the HRD parameter type is 1, the enhancementlayer image decoding section 201-2 recognizes the HRD parameter as aparameter used to decode only a corresponding layer, acquires the stateinformation of its own accumulation buffer, and monitors theaccumulation buffer. When the flag indicating the HRD parameter type is0, the enhancement layer image decoding section 201-2 recognizes the HRDparameter as a parameter used to perform a decoding process of acorresponding layer and a lower layer, acquires the state information ofthe accumulation buffer of the base layer image decoding section 201-1,and monitors the accumulation buffer. This process is performed on alayer and a sublayer (time layer). In the base layer image decodingsection 201-1, this process is performed on only a sublayer.

Through the decoding, the enhancement layer image decoding section 201-2decodes the encoded data of the enhancement layer, reconstructs theenhancement layer image information, and outputs the enhancement layerimage information.

The base layer image decoding section 201-1 and the enhancement layerimage decoding section 201-2 are appropriately referred to collectivelyas a “layer image decoding section 201.”

The decoding control section 202 controls the decoding process of thelayer image decoding sections 201, for example, in view of the referencerelation of the layer image decoding sections 201.

In the example of FIG. 20, one enhancement layer image decoding section201-2 is illustrated, but when there is an upper layer, enhancementlayer image decoding sections 201-3, 4, . . . that encode the upperlayer are provided for each of the upper layers.

<Example of Configuration of Layer Image Decoding Section>

FIG. 21 is a block diagram illustrating an example of a mainconfiguration of the enhancement layer image decoding section 201-2 ofFIG. 20. The base layer image decoding section 201-1 of FIG. 20 hasbasically the same configuration as the enhancement layer image decodingsection 201-2 of FIG. 21 except that a type of an image serving as atarget is different. For the sake of description, in the example of FIG.21, a configuration of the enhancement layer image decoding section201-2 will be described as an example.

As illustrated in FIG. 21, the enhancement layer image decoding section201-2 includes an accumulation buffer 211, a lossless decoding section212, an inverse quantization section 213, an inverse orthogonaltransform section 214, an operation section 215, a loop filter 216, ascreen reordering buffer 217, and a D/A converting section 218. Theenhancement layer image decoding section 201-2 further includes a framememory 219, a selecting section 220, an intra prediction section 221, amotion prediction/compensation section 222, and a selecting section 223.The enhancement layer image decoding section 201-2 further includes anHRD type decoding section 224.

The accumulation buffer 211 is a receiving section that receives thetransmitted enhancement layer encoded data. The accumulation buffer 211receives and accumulates the transmitted enhancement layer encoded data,and supplies the encoded data to the lossless decoding section 212 at acertain timing. Information necessary for decoding of the predictionmode information or the like is added to the enhancement layer encodeddata. The flag indicating the HRD parameter type and the HRD parameterare added to the enhancement layer encoded data as well.

When there is a request from the HRD type decoding section 224, theaccumulation buffer 211 supplies information indicating a state of theaccumulation buffer 211. Further, for example, when there is anenhancement layer image decoding section 201-3 of an upper layer asindicated by a dotted line, and there is a request from its HRD typedecoding section 224, the accumulation buffer 211 supplies theinformation indicating the state of the accumulation buffer 211.

The lossless decoding section 212 decodes the information that has beenencoded by the lossless encoding section 116 and supplied from theaccumulation buffer 211 according to a scheme corresponding to theencoding scheme of the lossless encoding section 116. The losslessdecoding section 212 supplies quantized coefficient data of adifferential image obtained by the decoding to the inverse quantizationsection 213.

Further, the lossless decoding section 212 appropriately extracts andacquires the NAL unit including the video parameter set (VPS), thesequence parameter set (SPS), the picture parameter set (PPS), and thelike which are included in the enhancement layer encoded data. Thelossless decoding section 212 extracts the information related to theoptimal prediction mode from the information, determines which of theintra prediction mode and the inter prediction mode has been selected asthe optimal prediction mode based on the information, and supplies theinformation related to the optimal prediction mode to one of the intraprediction section 221 and the motion prediction/compensation section222 that corresponds to the mode determined to have been selected.

In other words, for example, in the enhancement layer image decodingsection 201-2, when the intra prediction mode is selected as the optimalprediction mode, the information related to the optimal prediction modeis supplied to the intra prediction section 221. Further, for example,in the enhancement layer image decoding section 201-2, when the interprediction mode is selected as the optimal prediction mode, theinformation related to the optimal prediction mode is supplied to themotion prediction/compensation section 222.

Further, the lossless decoding section 212 extracts informationnecessary for inverse quantization such as the quantization matrix orthe quantization parameter from the NAL unit, and supplies the extractedinformation to the inverse quantization section 213. Further, thelossless decoding section 212 extracts the flag indicating the HRDparameter type and the HRD parameter, for example, from the VPS, andsupplies the extracted flag indicating the HRD parameter type and theHRD parameter to the HRD type decoding section 224.

The inverse quantization section 213 inversely quantizes the quantizedcoefficient data obtained through the decoding performed by the losslessdecoding section 212 according to a scheme corresponding to thequantization scheme of the quantization section 115. The inversequantization section 213 is the same processing section as the inversequantization section 118. In other words, the description of the inversequantization section 213 can be applied to the inverse quantizationsection 118 as well. Here, it is necessary to appropriately change andread a data input/output destination or the like according to a device.The inverse quantization section 213 supplies the obtained coefficientdata to the inverse orthogonal transform section 214.

The inverse orthogonal transform section 214 performs the inverseorthogonal transform on the coefficient data supplied from the inversequantization section 213 according to a scheme corresponding to theorthogonal transform scheme of the orthogonal transform section 114. Theinverse orthogonal transform section 214 is the same processing sectionas the inverse orthogonal transform section 119. In other words, thedescription of the inverse orthogonal transform section 214 can beapplied to the inverse orthogonal transform section 119 as well. Here,it is necessary to appropriately change and read a data input/outputdestination or the like according to a device

The inverse orthogonal transform section 214 obtains decoded residualdata corresponding to residual data that is not subjected to theorthogonal transform in the orthogonal transform section 114 through theinverse orthogonal transform process. The decoded residual data obtainedthrough the inverse orthogonal transform is supplied to the operationsection 215. Further, the predictive image is supplied from the intraprediction section 221 or the motion prediction/compensation section 222to the operation section 215 via the selecting section 223.

The operation section 215 adds the decoded residual data and thepredictive image, and obtains decoded image data corresponding to theimage data from which the predictive image is not subtracted by theoperation section 113. The operation section 215 supplies the decodedimage data to the loop filter 216.

The loop filter 216 appropriately performs the filter process such asthe deblock filter, the adaptive offset filter, or the adaptive loopfilter on the supplied decoded image, and supplies the resultant imageto the screen reordering buffer 217 and the frame memory 219. Forexample, the loop filter 216 removes the block distortion of the decodedimage by performing the deblock filter process on the decoded image.Further, for example, the loop filter 216 improves the image quality byperforming the loop filter process on the deblock filter process result(the decoded image from which the block distortion has been removed)using the Wiener filter. The loop filter 216 is the same processingsection as the loop filter 121.

Further, the decoded image output from the operation section 215 can besupplied to the screen reordering buffer 217 or the frame memory 219without intervention of the loop filter 216. In other words, part or allof the filter process performed by the loop filter 216 can be omitted.

The screen reordering buffer 217 reorders the decoded image. In otherwords, the order of the frames reordered in the encoding order by thescreen reordering buffer 112 is reordered in the original display order.The D/A converting section 218 performs D/A conversion on the imagesupplied from the screen reordering buffer 217, and outputs theconverted image to be displayed on a display (not illustrated).

The frame memory 219 stores the supplied decoded image, and supplies thestored decoded image to the selecting section 220 as the reference imageat a certain timing or based on an external request, for example, fromthe intra prediction section 221, the motion prediction/compensationsection 222, or the like.

The frame memory 219 sets the stored decoded image as informationrelated to decoding of the enhancement layer, and supplies theinformation to the enhancement layer image decoding section 201-2 of anupper layer.

The selecting section 220 selects the supply destination of thereference image supplied from the frame memory 219. When an imageencoded by the intra coding is decoded, the selecting section 220supplies the reference image supplied from the frame memory 219 to theintra prediction section 221. Further, when an image encoded by theinter coding is decoded, the selecting section 220 supplies thereference image supplied from the frame memory 219 to the motionprediction/compensation section 222.

For example, the information indicating the intra prediction modeobtained by decoding the header information is appropriately suppliedfrom the lossless decoding section 212 to the intra prediction section221. The intra prediction section 221 generates the predictive image byperforming the intra prediction using the reference image acquired fromthe frame memory 219 in the intra prediction mode used in the intraprediction section 124. The intra prediction section 221 supplies thegenerated predictive image to the selecting section 223.

The motion prediction/compensation section 222 acquires information(optimal prediction mode information, reference image information, andthe like) obtained by decoding the header information from the losslessdecoding section 212.

The motion prediction/compensation section 222 generates the predictiveimage by performing the inter prediction using the reference imageacquired from the frame memory 219 in the inter prediction modeindicated by the optimal prediction mode information acquired from thelossless decoding section 212. Although not illustrated, in the motionprediction/compensation section 222, the reference image supplied fromthe frame memory 219 of the base layer image decoding section 201-1 isalso referred to as necessary.

The selecting section 223 supplies the predictive image supplied fromthe intra prediction section 221 or the predictive image supplied fromthe motion prediction/compensation section 222 to the operation section215. Then, the operation section 215 adds the predictive image generatedusing the motion vector to the decoded residual data (the differentialimage information) supplied from the inverse orthogonal transformsection 214 to decode the original image.

The HRD type decoding section 224 acquires the information indicatingthe accumulation state from the accumulation buffer 211 or theaccumulation buffer (the lower layer) 211 of the base layer imagedecoding section 201-1 according to the flag indicating the HRDparameter type supplied from the lossless decoding section 212. The HRDtype decoding section 224 monitors the accumulation buffer 211 based onthe acquired information according to the HRD parameter corresponding tothe flag indicating the HRD parameter type.

<Example of Configuration of Accumulation Buffer and HRD Type DecodingSection>

FIG. 22 is a block diagram illustrating an example of a configuration ofthe accumulation buffer and the HRD type decoding section of FIG. 21.

In an example of FIG. 22, the accumulation buffer 211 is configured toinclude a partial accumulation buffer 231 and a whole accumulationbuffer 232.

The HRD type decoding section 224 is configured to include a layer HRDparameter monitoring section 241, a time layer HRD parameter monitoringsection 242, a HRD parameter type decoding section 243, and a time HRDparameter type decoding section 244.

The partial accumulation buffer 231 is configured with accumulationbuffers that accumulate encoded data related to each upper time layeramong the encoded data (codes) accumulated in the whole accumulationbuffer 232. The information indicating the state of each accumulationbuffer is supplied to the time layer HRD parameter monitoring section242 on request.

The whole accumulation buffer 232 accumulates the encoded data (codes)encoded by the enhancement layer image encoding section 101-2. Theinformation indicating the state of the whole accumulation buffer of thewhole accumulation buffer 232 is supplied to the layer HRD parametermonitoring section 241 and the time layer HRD parameter monitoringsection 242 on request. Further, there are cases in which there is anenhancement layer image decoding section 201-3 of an upper layer asindicated by a dotted line. In this case, when there is a request fromthe HRD type decoding section (upper layer) 224 of the enhancement layerimage decoding section 201-3, the information indicating the state ofthe whole accumulation buffer of the whole accumulation buffer 232 isalso supplied to the HRD type decoding section (upper layer) 224.

The layer HRD parameter monitoring section 241 receives the HRDparameter supplied from the lossless decoding section 212, and acquiresthe HRD parameter corresponding to the flag indicating the HRD parametertype supplied from the HRD parameter type decoding section 243. Thelayer HRD parameter monitoring section 241 monitors the accumulationbuffer 211 based on the acquired HRD parameter.

In other words, the layer HRD parameter monitoring section 241 acquiresinformation indicating the state of the whole accumulation buffer 232and information indicating the state of the accumulation buffer (thelower layer) 211 of the base layer image decoding section 201-1according to the flag indicating the HRD parameter type supplied fromthe HRD parameter type decoding section 243.

In the case of the HRD parameter type in which the flag indicates 1, theinformation indicating the state of the whole accumulation buffer 232 isacquired. In the case of the HRD parameter type in which the flagindicates 0, the information indicating the state of the wholeaccumulation buffer 232 and the information indicating the state of theaccumulation buffer (the lower layer) 211 of the base layer imagedecoding section 201-1 are acquired. Practically, information isacquired from the whole accumulation buffer 232 of the accumulationbuffer of the base layer image decoding section 201-1.

The time layer HRD parameter monitoring section 242 receives the timelayer HRD parameter supplied from the lossless decoding section 212, andacquires the time layer HRD parameter corresponding to the flagindicating the sub HRD parameter type supplied from the time HRDparameter type decoding section 244. The layer HRD parameter monitoringsection 241 monitors the accumulation buffer 211 based on the acquiredtime layer HRD parameter.

In other words, the time layer HRD parameter monitoring section 242acquires the information indicating the state of the whole accumulationbuffer 232 and information indicating the state of the accumulationbuffer of the corresponding time layer of the partial accumulationbuffer 231 according to the flag indicating the sub HRD parameter typesupplied from the time HRD parameter type decoding section 244.

When the flag indicating the sub HRD parameter type is 1, theinformation indicating the state of the accumulation buffer of thecorresponding time layer of the partial accumulation buffer 231 isacquired. When the flag indicating the sub HRD parameter type is 0, theinformation indicating the state of the whole accumulation buffer 232and the information indicating the state of the accumulation buffer ofthe corresponding time layer of the partial accumulation buffer 231 areacquired.

The HRD parameter type decoding section 243 receives the HRD parametertype flag supplied from the lossless decoding section 212. Then, the HRDparameter type decoding section 243 selects a flag indicating an HRDparameter type corresponding to a layer configuration of an actualstream or a configuration or a function of a device among the receivedflags, and supplies the selected flag to the layer HRD parametermonitoring section 241.

The time HRD parameter type decoding section 244 receives the sub HRDparameter type flag supplied from the lossless decoding section 212.Then, the time HRD parameter type decoding section 244 selects a flagindicating a sub HRD parameter type corresponding to a layerconfiguration of an actual stream or a configuration or a function of adevice among the received flags, and supplies the selected flag to thelayer HRD parameter monitoring section 241.

In the case of the HRD parameter described above with reference to FIGS.8 and 9, two types (a type of only a corresponding layer and a type of acorresponding layer and a lower layer) are described, and thus any onetype can be selected by a configuration or a function of an actualstream or device. On the other hand, in the case of the HRD parameterdescribed above with reference to FIG. 7, only one type is described,and thus the HRD parameter is ignored when a type of a configuration ora function of an actual stream or device is different from a describedtype.

<Flow of Decoding Process>

Next, the flow of the process performed by the scalable decoding device200 will be described. First, an example of the flow of the decodingprocess will be described with reference to a flowchart of FIG. 23.

When the decoding process starts, in step S201, the decoding controlsection 202 of the scalable decoding device 200 decides a layer of aprocessing target, for example, in view of the reference relation of animage.

In step S202, the base layer image decoding section 201-1 performs alayer decoding process under control of the decoding control section202. The layer decoding process will be described later with referenceto FIG. 24. When the process of step S202 ends, the process proceeds tostep S203.

In step S203, the decoding control section 202 determines whether or notall the main layers have been processed. When it is determined thatthere is a non-processed main layer, the process proceeds to step S204.

In step S204, the decoding control section 202 sets a next non-processedmain layer as a processing target (current main layer). When the processof step S204 ends, the process returns to step S202. In step S202, theenhancement layer image decoding section 201-2 performs the layerdecoding process under control of the decoding control section 202. Theprocess of steps S202 to S204 is repeatedly performed to encode the mainlayers as described above. The process of step S202 may be processed inparallel by a plurality of layer image decoding sections 201 having noreference relation.

Then, when all the main layers are determined to have been processed instep S203, the decoding process ends.

<Flow of Layer Decoding Process>

Next, an example of the flow of the layer decoding process performed instep S202 of FIG. 23 will be described with reference to a flowchart ofFIG. 24. An example of FIG. 24 will be described in connection with anexample of the enhancement layer image decoding section 201-2.

When the layer decoding process starts, in step S211, the accumulationbuffer 211 of the enhancement layer image decoding section 201-2accumulates the bitstreams of the enhancement layer transmitted from theencoding side.

In step S212, the lossless decoding section 212 decodes the bitstream(the encoded differential image information) of the enhancement layersupplied from the accumulation buffer 211. In other words, the Ipicture, the P picture, and the B picture encoded by the losslessencoding section 116 are decoded. At this time, various kinds ofinformation other than the differential image information included inthe bitstream, such as the header information, are also decoded. Theflag indicating the HRD parameter type supplied from the losslessdecoding section 212 and the HRD parameter are supplied to the HRD typedecoding section 224.

In step S213, the HRD type decoding section 224 performs an HRDparameter decoding process. The HRD parameter decoding process will bedescribed later with reference to FIG. 26.

The HRD parameter is decoded in step S213, and the accumulation buffer211 is monitored based on the decoded HRD parameter so that no overflowor underflow occurs.

In step S214, the inverse quantization section 213 inversely quantizesthe quantized coefficients obtained in the process of step S212.

In step S215, the inverse orthogonal transform section 214 performs theinverse orthogonal transform on a current block (a current TU).

In step S216, the intra prediction section 221 or the motionprediction/compensation section 222 performs the prediction process, andgenerates the predictive image. In other words, the prediction processis performed in the prediction mode that is determined to have beenapplied at the time of encoding in the lossless decoding section 212.More specifically, for example, when the intra prediction is applied atthe time of encoding, the intra prediction section 221 generates thepredictive image in the intra prediction mode recognized to be optimalat the time of encoding. Further, for example, when the inter predictionis applied at the time of encoding, the motion prediction/compensationsection 222 generates the predictive image in the inter prediction moderecognized to be optimal at the time of encoding.

In step S217, the operation section 215 adds the predictive imagegenerated in step S216 to the differential image information generatedby the inverse orthogonal transform process of step S215. As a result,the original image is decoded.

In step S218, the loop filter 216 appropriately performs the loop filterprocess on the decoded image obtained in step S217.

In step S219, the screen reordering buffer 217 reorders the image thathas been subjected to the filter process in step S218. In other words,the order of the frames reordered for encoding through the screenreordering buffer 112 is reordered in the original display order.

In step S220, the D/A converting section 218 performs D/A conversion onthe image in which the order of the frames is reordered in step S219.The image is output to a display (not illustrated), and the image isdisplayed.

In step S221, the frame memory 219 stores the image that has beensubjected to the loop filter process in step S218.

When the process of step S221 ends, the base layer decoding processends, and the process returns to FIG. 23.

<Flow of HRD Parameter Decoding Process>

Next, an example of the flow of the HRD parameter decoding processperformed in step S213 of FIG. 24 will be described with reference to aflowchart of FIG. 25.

The HRD parameter type decoding section 243 receives the flag indicatingthe HRD parameter type of the corresponding layer in step S231. Then,the HRD parameter type decoding section 243 supplies, for example, aflag indicating an HRD parameter type corresponding to a layerconfiguration of an actual stream among the received flags to the layerHRD parameter monitoring section 241.

In step S232, the layer HRD parameter monitoring section 241 receivesthe HRD parameter supplied from the lossless decoding section 212, andacquires the HRD parameter corresponding to the flag indicating the HRDparameter type supplied from the HRD parameter type decoding section243.

In step S233, the time HRD parameter type decoding section 244 receivesthe flag indicating the HRD parameter type supplied from the losslessdecoding section 212. Then, the time HRD parameter type decoding section244 supplies, for example, a flag indicating a sub HRD parameter typecorresponding to a layer configuration of an actual stream among thereceived flags to the layer HRD parameter monitoring section 241.

In step S234, the time layer HRD parameter monitoring section 242receives the time layer HRD parameter supplied from the losslessdecoding section 212, and acquires the time layer HRD parametercorresponding to the sub HRD parameter type flag supplied from the timeHRD parameter type decoding section 244.

In step S235, the time layer HRD parameter monitoring section 242determines whether or not the process has ended on all the time layers.When the process is determined not to have ended on any one of the timelayers in step S235, the process returns to step S233, and thesubsequent process is repeated.

When the process is determined to have ended on all the time layers instep S235, the process proceeds to step S236. In step S236, the layerHRD parameter monitoring section 241 and the time layer HRD parametermonitoring section 242 perform an accumulation buffer monitoring processwhich will be described below.

<Flow of Accumulation Buffer Monitoring Process>

Next, the accumulation buffer monitoring process will be described withreference to a flowchart of FIG. 26. The accumulation buffer monitoringprocess is an example using the HRD parameter type flag according to thepresent technology, and the present technology is not limited to thisexample. For the sake of description, a timing at which this process isperformed is described as being within the HRD parameter decodingprocess, but the present technology is not limited to this example, andthis process may be performed, for example, at any timing within thelayer decoding process of FIG. 24.

In step S251, the layer HRD parameter monitoring section 241 determineswhether or not the flag indicating the HRD parameter type of thecorresponding layer is 1. When the flag indicating the HRD parametertype of the corresponding layer is determined to be 1 in step S251, theprocess proceeds to step S252.

In step S252, the layer HRD parameter monitoring section 241 acquiresthe information indicating the state of the whole accumulation buffer232, and in step S253, the layer HRD parameter monitoring section 241monitors the whole accumulation buffer 232 of the corresponding layeraccording to the HRD parameter of the corresponding layer using theacquired information.

When the flag indicating the HRD parameter type of the correspondinglayer is determined to be 0 in step S251, the process proceeds to stepS254.

In step S254, the layer HRD parameter monitoring section 241 acquiresthe information indicating the state of the whole accumulation buffer232, and in step S255, the layer HRD parameter monitoring section 241acquires the information indicating the state of the whole accumulationbuffer 232 of the lower layer.

Then, in step S256, the layer HRD parameter monitoring section 241monitors the whole accumulation buffer 232 of the corresponding layerusing the information acquired in steps S254 and S255 according to theHRD parameter of the corresponding layer.

In step S257, the time layer HRD parameter monitoring section 242determines whether or not the flag indicating the HRD parameter type ofthe corresponding time layer is 1. When the flag indicating the HRDparameter type of the corresponding time layer is determined to be 1 instep S257, the process proceeds to step S258.

In step S258, the time layer HRD parameter monitoring section 242acquires information indicating the state of the accumulation buffer ofeach corresponding time layer of the partial accumulation buffer 231.

In step S259, the time layer HRD parameter monitoring section 242monitors (each buffer of) the partial accumulation buffer 231 using theinformation acquired in step S258 according to the HRD parameter of eachtime layer.

When the flag indicating the HRD parameter type of the correspondingtime layer is determined to be 0 in step S257, the process proceeds tostep S260.

In step S260, the time layer HRD parameter monitoring section 242acquires the information indicating the state of the whole accumulationbuffer 232.

In step S261, the time layer HRD parameter monitoring section 242acquires the information indicating the state of the accumulation bufferof each corresponding time layer of the partial accumulation buffer 231.

In step S259, the time layer HRD parameter monitoring section 242monitors (each buffer of) the partial accumulation buffer 231 using theinformation acquired in steps S260 and S261 according to the HRDparameter of each time layer.

As described above, at least one flag is set to indicate whether the HRDparameter is the parameter for performing decoding of only acorresponding layer or the parameter for performing the decoding processof a corresponding layer and a lower layer, and thus it is possible toperform a decoding process at a proper timing.

This flag may be transmitted to the decoding side as supplementalenhancement information (SEI).

Here, it is difficult to detect whether the decoding process isperformed by a single decoding device or a plurality of decoding devicesas described above with reference to FIG. 6. In this regard, the exampleof setting the information indicating whether the HRD parameter is theparameter for performing the decoding process of only a correspondinglayer or the parameter for performing the decoding process of acorresponding layer and a lower layer has been described above.

However, the current HEVC supports only the HRD parameter of the example(that is, the example in which the decoding process of the multiplelayers is performed by a single decoding device) of ex11 illustrated inFIG. 6. In other words, in the current HEVC, the HRD parameter of theexample of ex11 is set to the video parameter set (VPS) and transmittedto the decoding side.

In this regard, in the present technology, a technique of transmittingan HRD parameter of the example (that is, the example in which thedecoding process of the multiple layers is performed by a plurality ofdecoding devices) of ex12 illustrated in FIG. 6 to the decoding sidethrough vps_extension in the scalable HEVC is proposed as a thirdembodiment.

3. Third Embodiment Example of Syntax of Vps_Extension

FIG. 27 is a diagram illustrating an example of syntax of vps_extension.In an example of FIG. 27, i indicates the number of layer_sets, and jindicates the number of layer ids. Further, starting from j=1 indicatesthat there is only a base layer when j=0, and in this case, theprocessing methods of ex11 and ex12 are not different but all the same.

In an example of FIG. 27, layer_set_hrd_layer_info_present_flag[i][j] isset for each layer_id_included_flag[i][j]. Whenlayer_set_hrd_layer_info_present_flag[i][j] is 1, it indicates that theHRD parameter corresponding to the example of ex12 is present (invps_extension), and in this case, the HRD parameter corresponding to theexample of ex12 is defined in next and subsequent rows.

Further, the HRD parameter corresponding to the example of ex12 may beset in sps (sequence parameter set)_extension as illustrated in FIG. 28.

<Example of Syntax of Sps_Extension>

FIG. 28 is a diagram illustrating an example of syntax of sps_extension.

In an example of FIG. 28, layer_set_hrd_layer_info_present_flag is set.When this flag is 1, it indicates that the HRD parameter correspondingto the example of ex12 is present (in sps_extension), and in this case,the HRD parameter corresponding to the example of ex12 is defined in thenext row.

In the example of FIGS. 27 and 28, the HRD parameter is set for eachlayer_set. layer_set is set in the VPS as illustrated in FIG. 29.

<Example of Syntax of VPS>

FIG. 29 is a diagram illustrating an example of syntax of a VPS. Numberson the left of each row are row numbers added for description.

In a 16th row of FIG. 29, the number of layer_sets is set asvps_num_layer_sets_minus1.

In 17th to 19th rows, it is described whether or not a layer of id[j] isincluded in layer_set of [i] as layer_id_included_flag[i][j].layer_id_included_flag[i][j] will be described in detail in semanticsillustrated in FIG. 30.

In a 27th row, the number of hrd parameters is set in a vps asvps_num_hrd_parameters. In a 29th row, hrd_parameters is associated withlayer_set as hrd_layer_set_idx[i]. In a 32nd row, the HRD parameter ofthe example of ex11 is described as described above.

In a 35th row, vps_extension_flag indicating the presence or absence ofvps_extension is described.

<Example of Semantics of Layer_Id_Included_Flag[i][j]>

FIG. 30 illustrates an example of semantics oflayer_id_included_flag[i]j[j].

layer_id_included_flag[i][j] equal to 1 specifies that the value ofnuh_layer_id equal to j is included in the layer identifier listlayerSetLayeridList[i]. layer_id_included_flag[i][j] equal to 0specifies that the value of nuh_layer_id equal to j is not included inthe layer identifier list layerSetLayerIdList[i].

The value of numLayersInIdList[0] is set equal to 1 and the value oflayerSetLayerIdList[0][0] is set equal to 0.

For each value of i in the range of 1 to vps_num_layer_sets_minus1,inclusive, the variable numLayersInIdList[i] and the layer identifierlist layerSetLayerIdList[i] are derived as follows:

n=0

for (m=0; m<=vps_max_layer_id; m++)

-   -   if (layer_id_included_flag[i][m])        -   layerSetLayerIdList[i][n++]=m

numLayersInIdList[i]=n

For each value of i in the range of 1 to vps_num_layer_sets_minus1,inclusive, numLayersInIdList[i] shall be in the range of 1 tovps_max_layers_minus1+1, inclusive.

When numLayersInIdList[iA] is equal to numLayersInIdList[iB] for any iAand iB in the range of 0 to vps_num_layer_sets_minus1, inclusive, withiA not equal to iB, the value of layerSetLayerIdList[iA][n] shall not beequal to layerSetLayerIdList[iB][n] for at least one value of n in therange of 0 to numLayersInIdList[iA], inclusive.

A layer set is identified by the associated layer identifier list. Thei-th layer set specified by the VPS is associated with the layeridentifier list layerSetLayerIdList[i], for i in the range of 0 tovps_num_layer_sets_minus1, inclusive.

A layer set consists of all operation points that are associated withthe same layer identifier list.

Each operation point is identified by the associated layer identifierlist, denoted as OpLayerIdList, which consists of the list ofnuh_layer_id values of all NAL units included in the operation point, inincreasing order of nuh_layer_id values, and a variable OpTid, which isequal to the highest TemporalId of all NAL units included in theoperation point. The bitstream subset associated with the operationpoint identified by OpLayerIdList and OpTid is the output of thesub-bitstream extraction process as specified in clause 10 with thebitstream, the target highest TemporalId equal to OpTid, and the targetlayer identifier list equal to OpLayerIdList as inputs. TheOpLayerIdList and OpTid that identify an operation point are alsoreferred to as the OpLayerIdList and OpTid associated with the operationpoint, respectively.

Particularly, as surrounded by a frame in FIG. 30, it is described thatlayer_set consists of all operation points that are associated with thesame layer identifier list, and some bitstreams that can be extractedamong bitstreams are associated with operation points identified byOplayerIdList.

Specifically, layer_set is set, for example, as illustrated in FIG. 31.

For example, when layers 0, 1, and 2 are included in LayerSet[1], andthe layers 0 and 2 are included in LayerSet[2], layer_id_included_flagis set as follows.

layer_id_included_flag[1][0]=1 is set, which indicates that the layer 0is included in LayerSet[1]. Further, layer_id_included_flag[1][1]=1 isset, which indicates that the layer 1 is included in LayerSet[1], andlayer_id_included_flag[1][2]=1 is set, which indicates that the layer 2is included in LayerSet[1].

layer_id_included_flag[2][0]=1 is set, which indicates that the layer 0is included in LayerSet[2]. Further, layer_id_included_flag[2][1]=0 isset, which indicates that the layer 1 is not included in LayerSet[2],and layer_id_included_flag[2][2]=1 is set, which indicates that thelayer 2 is included in LayerSet[2].

As described above, the flag indicating that there is the HRD parametercorresponding to the example of ex11 of FIG. 6 and the HRD parametercorresponding to the example of ex11 are transmitted to the decodingside through the vps. On the other hand, the flag indicating that thereis the HRD parameter corresponding to the example of ex12 of FIG. 6 andthe HRD parameter corresponding to the example of ex12 are transmittedto the decoding side through vps_extension. Thus, the decoding side canperform a decoding process at a proper timing.

Further, the flag indicating that there is the HRD parametercorresponding to the example of ex12 may also be transmitted to thedecoding side as an SEI message.

4. Fourth Embodiment Another Example of Buffer Schedule ManagementMethod

Meanwhile, in order to prevent overflow or underflow of a buffer, it isnecessary to apply any one of the following methods to a buffer schedulemanagement.

A first method is a method using the parameter transmitted in the HRDparameter syntax in the first to third embodiments.

A second method is a method using buffering_period_SEI andpicture_timing_SEI.

A third method is a method using a parameter transmitted in a layerhigher than a video layer such as a time stamp (for example, a PTS or aDTS) in a system layer.

Of these methods, the method using buffering_period_SEI according to thesecond method will be described below.

<Syntax of Buffering_Period_SEI>

FIG. 32 is a diagram illustrating an example of syntax ofbuffering_period_SEI. Numbers on the left of each row are row numbersadded for description.

In a 2nd row of FIG. 32, a parameter of buffering_period is set asbp_seq_parameter_set_id, and can be associated with an SPS.

In subsequent rows, a schedule management parameter of an accumulationbuffer by accumulation from a lower layer is set.

Meanwhile, a technique of defining a parameter for the case of ex12 forperforming a decoding process of decoding respective layers including alayer to be referred to through separate decoding devices in addition tothe case of ex11 of performing a decoding process by a single decodingdevice as a parameter for buffer management by hdr_parameters( ) inimage compression information or sub image compression information asdescribed above with reference to FIG. 6 has been proposed.

hdr_parameters( ) according to the first method can be transmitted inassociation with a VPS or an SPS, and in the case of the former,hdr_parameters( ) can be transmitted for a layer set associated with aVPS as well as a single layer.

However, buffering_period_SEI illustrated in FIG. 32 can be associatedwith only an SPS. Thus, it is difficult to transmit a parameterassociated with a plurality of layer sets as in hdr_parameters( ) in aVPS.

In this regard, in the present technology, a schedule management of anaccumulation buffer by buffering_period_SEI is performed by syntaxillustrated in FIGS. 33 to 35.

buffering_period_SEI according to the present technology differs frombuffering_period_SEI illustrated in FIG. 32 in the following points.

In other words, a first difference lies in that buffering_period_SEIaccording to the present technology can be associated with a VPS as wellas an SPS. A second difference lies in that a parameter can be set foreach layer set defined in a VPS when associated with a VPS. A thirddifference lies in that it is possible to set a parameter when alllayers included in a layer set are decoded by a single decoding deviceand a parameter when respective layers are decoded by separate decodingdevices as illustrated in FIG. 6.

FIGS. 33 to 35 are diagrams illustrating an example of syntax ofbuffering_period_SEI. Numbers on the left of each row are row numbersadded for description.

In an example of FIG. 33, associated_parameter_set_flag is set in a 2ndrow. associated_parameter_set_flag is a flag designating which of a VPSand an SPS is associated with buffering_period_SEI. Whenassociated_parameter_set_flag is 0, it indicates an association with aVPS, and when associated_parameter_set_flag is 1, it indicates anassociation with an SPS.

A parameter when associated_parameter_set_flag is 0 (VPS) is describedin 3rd to 11th rows. bp_video_parameter_set_id in a 4th row indicates acorresponding VPS, and vps_num_bp_parameters in a 5th row indicates thenumber of transmitted bp_parameters.

bp_layer_set_idx in a 7th row indicates a layer set corresponding toeach bp_parameter, and syntax of layer_buffering_period of FIGS. 34 and35 is read with layer_buffering_period in a 10th row.

A parameter when associated_parameter_set_flag is 1 (SPS) is describedas indicated by else in 12th to 15th rows.

bp_seq_parameter_set_id in a 13th row indicates a corresponding SPS, andsyntax of layer_buffering_period of FIGS. 34 and 35 is read withlayer_buffering_period in a 14th row.

In other words, according to the syntax of FIG. 33, in the case of theVPS, the syntax of FIG. 34 is read by the number of layer sets, and inthe case of the SPS, the syntax of FIGS. 34 and 35 is read once.

As described above, when associated_parameter_set_flag is 0 (VPS), it ispossible to transmit the parameter for buffer management for the layerset designated by the VPS according to layer_buffering_period_SET syntaxof FIGS. 34 and 35.

In the transmission of the parameter related to the NAL and the VCL ofFIGS. 34 and 35, layer_specific_parameters_present_flag serving as aflag indicating whether or not a parameter of only a corresponding layeris transmitted is set as illustrated in 18th and 38th rows. When thisflag is 1, it indicates that a parameter of only a corresponding layerdescribed in 19th to 27th rows and 39th to 47th rows is transmitted. Inother words, when layer_specific_parameters_present_flag is 1, it ispossible to transmit a parameter for performing a decoding process as inex12 in addition to ex11 of FIG. 6.

In the example of FIGS. 34 and 35, buffering_period_SEI is basically thesame as buffering_period_SEI described above with reference to FIG. 32except for the above-described points, and in the other rows, a schedulemanagement parameter of an accumulation buffer by accumulation from alower layer is set.

Thus, when schedule management of an accumulation buffer bybuffering_period_SET is performed, it is possible to manage a layer setas well as a single layer. Further, it is possible to perform a schedulemanagement both when all layers included in a layer set are decoded by asingle decoding device and when respective layers are decoded byseparate decoding devices.

<Scalable Encoding Device>

A scalable encoding device in the case of buffering_period_SEI hasbasically the same configuration as in the case of the HRD parameter.Thus, an example of a configuration of a scalable encoding device in thecase of buffering_period_SEI will be described with reference to FIG.10.

In other words, as in the case of the HRD parameter, the base layerimage encoding section 101-1 acquires image information (base layerimage information) of the base layer. The base layer image encodingsection 101-1 encodes the base layer image information without referringto other layers, generates encoded data (base layer encoded data) of thebase layer, and outputs the generated encoded data.

As in the case of the HRD parameter, the enhancement layer imageencoding section 101-2 acquires image information (enhancement layerimage information) of the enhancement layer. The enhancement layer imageencoding section 101-2 encodes the enhancement layer image information.At this time, the enhancement layer image encoding section 101-2performs inter-layer prediction with reference to information related toencoding of the base layer as necessary.

Further, buffer management information is supplied from the base layerimage encoding section 101-1 to the enhancement layer image encodingsection 101-2 as necessary. Unlike the case of the HRD parameter, theenhancement layer image encoding section 101-2 designates an associatedparameter set, and designates a parameter of each layer set or aparameter for a sequence according to the designated parameter set.Then, the enhancement layer image encoding section 101-2 sets thedesignated parameter with reference to the buffer management informationsupplied from the base layer image encoding section 101-1.

Further, unlike the case of the HRD parameter, the enhancement layerimage encoding section 101-2 setslayer_specific_parameters_present_flag, and sets a parameter of eachlayer according to a value of layer_specific_parameters_present_flag.Then, the enhancement layer image encoding section 101-2 encodesbuffering_period_SEI and layer_buffering_period_SEI including the setparameters, and supplies the encoded information to a lossless encodingsection 301.

The enhancement layer image encoding section 101-2 generates encodeddata (enhancement layer encoded data) of the enhancement layer throughthe above encoding, and outputs the generated encoded data.

As in the case of the HRD parameter, the encoding control section 102controls the encoding process of the layer image encoding sections 101,for example, in view of the reference relation of the layer imageencoding sections 101.

<Example of Configuration of Layer Image Encoding Section>

FIG. 36 is a block diagram illustrating an example of a mainconfiguration of the enhancement layer image encoding section 101-2 inthe case of buffering_period_SEI.

Further, the base layer image encoding section 101-1 in the case ofbuffering_period_SEI has basically the same configuration as theenhancement layer image encoding section 101-2 of FIG. 36 except that atype of an image serving as a target is different. For the sake ofdescription, in the example of FIG. 36, a configuration of theenhancement layer image encoding section 101-2 will be described as anexample.

The enhancement layer image encoding section 101-2 of FIG. 36 differsfrom the enhancement layer image encoding section 101-2 of FIG. 11 inthat the lossless encoding section 116 is replaced with the losslessencoding section 301, the HRD type setting section 128 is not provided,and a buffering period SEI setting section 302 is added.

In other words, the enhancement layer image encoding section 101-2 ofFIG. 36 includes an A/D converting section 111, a screen reorderingbuffer 112, an operation section 113, an orthogonal transform section114, a quantization section 115, a lossless encoding section 301, anaccumulation buffer 117, an inverse quantization section 118, and aninverse orthogonal transform section 119. The enhancement layer imageencoding section 101-2 further includes an operation section 120, a loopfilter 121, a frame memory 122, a selecting section 123, an intraprediction section 124, a motion prediction/compensation section 125, apredictive image selecting section 126, and a rate control section 127.The enhancement layer image encoding section 101-2 further includes thebuffering period SEI setting section 302.

like the lossless encoding section 116 of FIG. 11, the lossless encodingsection 301 encodes the transform coefficients quantized in thequantization section 115 according to an arbitrary encoding scheme.Since coefficient data is quantized under control of the rate controlsection 127, the coding amount becomes a target value (or approaches atarget value) set by the rate control section 127.

Like the lossless encoding section 116, the lossless encoding section301 acquires information indicating an intra prediction mode or the likefrom the intra prediction section 124, and acquires informationindicating an inter prediction mode, differential motion vectorinformation, or the like from the motion prediction/compensation section125.

Further, unlike the lossless encoding section 116, the lossless encodingsection 301 acquires encoded information (syntax) oflayer_buffering_period_SEI from the buffering period SEI setting section302 in addition to buffering_period_SEI.

Further, like the lossless encoding section 116, the lossless encodingsection 301 appropriately generates an NAL unit of the enhancement layerincluding a sequence parameter set (SPS), a picture parameter set (PPS),and the like. Like the lossless encoding section 116, the losslessencoding section 301 encodes various kinds of information according toan arbitrary encoding scheme, and sets (multiplexes) the encodedinformation as part of encoded data (also referred to as an “encodedstream”). The lossless encoding section 301 supplies the encoded dataobtained by the encoding to be accumulated in the accumulation buffer117.

Further, unlike the lossless encoding section 116, for example, whenthere is an enhancement layer image encoding section 101-3 of an upperlayer as indicated by a dotted line, and there is a request from itsbuffering period SEI setting section 302, the lossless encoding section301 supplies management information of the accumulation buffer 117 tothe enhancement layer image encoding section 101-3 of the upper layer.

The accumulation buffer 117 temporarily holds the encoded data(enhancement layer encoded data) supplied from the lossless encodingsection 301. The accumulation buffer 117 outputs the held enhancementlayer encoded data to a recording device (recording medium), atransmission path, or the like (not illustrated) at a subsequent stageat a certain timing. In other words, the accumulation buffer 117 servesas a transmitting section that transmits the encoded data as well.

The buffering period SEI setting section 302 designates an associatedparameter set, and designates a parameter of each layer set or aparameter for a sequence according to the designated parameter set.Further, the buffering period SEI setting section 302 sets thedesignated parameter with reference to the buffer management informationsupplied from the lossless encoding section 301 (the lower layer) of thebase layer image encoding section 101-1. For example, this parameter isa parameter of accumulation from a lower layer. Further, the bufferingperiod SEI setting section 302 setslayer_specific_parameters_present_flag, and sets a parameter of eachlayer according to the set value oflayer_specific_parameters_present_flag.

The buffering period SEI setting section 302 encodesbuffering_period_SEI and layer_buffering_period_SEI including theparameters set as described above, and supplies the encoded informationto the lossless encoding section 301.

<Example of Configuration of Buffering Period SEI Setting Section>

FIG. 37 is a block diagram illustrating an example of a configuration ofthe buffering period SEI setting section of FIG. 36.

In an example of FIG. 37, the buffering period SEI setting section 302is configured to include an associated parameter set setting section311, a layer set buffer 312, a layer buffering period SEI settingsection 313, and a layer parameter transmission designating section 314.

The associated parameter set setting section 311 performs a designationrelated to associated_parameter_set_flag according to the user'soperation. In other words, the user designates which of a VPS (flag=0)and an SPS (flag=1) is associated with buffering_period_SEI. Theassociated parameter set setting section 311 designates a value ofassociated_parameter_set_flag, and supplies the designated value to thelossless encoding section 301 and the layer buffering period SEI settingsection 313.

In the case of associated_parameter_set_flag=0, that is, whenbuffering_period_SEI is associated with a VPS, information related to alayer set stored in a VPS of enhancement layer image compressioninformation is supplied and accumulated in the layer set buffer 312through the lossless encoding section 301. The layer set buffer 312accumulates the information related to the layer set, and supplies theinformation related to the layer set to the layer buffering period SEIsetting section 313 at a certain timing.

Further, the buffer management information in the base layer is suppliedfrom the lossless encoding section 301 of the base layer image encodingsection 101-1 to the layer buffering period SEI setting section 313.

The layer parameter transmission designating section 314 designateslayer_specific_parameters_present_flag according to the user'soperation. In other words, the user designates a value oflayer_specific_parameters_present_flag indicating whether or not aparameter setting of each layer is performed. The layer parametertransmission designating section 314 designates a value oflayer_specific_parameters_present_flag, and supplies the designatedvalue to the lossless encoding section 301 and the layer bufferingperiod SEI setting section 313.

The layer buffering period SEI setting section 313 performs the encodingprocess of buffering_period_SEI and layer_buffering_period_SE, andsupplies encoded information thereof to the lossless encoding section301.

Specifically, the layer buffering period SEI setting section 313 setsthe designated parameter according to associated_parameter_set_flagsupplied from the associated parameter set setting section 311 withreference to the buffer management information supplied from thelossless encoding section 301 (the lower layer) of the base layer imageencoding section 101-1. In other words, when a value ofassociated_parameter_set_flag is 1 (=VPS), the layer buffering periodSEI setting section 313 sets a parameter for each layer set based on theinformation related to the layer set supplied from the layer set buffer312. Further, when a value of associated_parameter_set_flag is 0 (=SPS),the layer buffering period SEI setting section 313 sets a parameter fora sequence.

Further, the layer buffering period SEI setting section 313 sets aparameter of each layer according to a value oflayer_specific_parameters_present_flag, that is, when a value oflayer_specific_parameters_present_flag is 1. Further, the layerbuffering period SEI setting section 313 encodes buffering_period_SEIand layer_buffering_period_SEI including the set parameter, and suppliesthe encoded information to the lossless encoding section 301.

<Flow of Encoding Process>

Next, the flow of the process performed by the scalable encoding device100 in the case of buffering_period_SEI will be described. The flow ofthe encoding process is basically the same as the flow of the encodingprocess described above with reference to FIG. 14, and a descriptionthereof is omitted.

<Flow of Layer Encoding Process>

Next, the layer encoding process in step S102 of FIG. 14 will bedescribed with reference to a flowchart of FIG. 38. In steps S311 toS323, S326, and S327 of FIG. 38, basically the same processes as insteps Sill to S123, S126, and S127 of FIG. 15 are performed, and thus adescription thereof is omitted.

In other words, in step S324, the buffering period SEI setting section302 performs a buffering period SEI encoding process. The bufferingperiod SEI encoding process will be described later with reference toFIG. 39, and through this process, the respective parameters are set,and information of buffering_period_SEI and layer_buffering_period_SEIincluding the set parameters is encoded and supplied to the losslessencoding section 301.

In step S325, the lossless encoding section 301 encodes the coefficientsquantized in the process of step S318. In other words, lossless codingsuch as variable length coding or arithmetic coding is performed on datacorresponding to a differential image.

At this time, the lossless encoding section 301 encodes the informationrelated to the prediction mode of the predictive image selected in theprocess of step S315, and adds the encoded information to the encodeddata obtained by encoding the differential image. In other words, thelossless encoding section 301 also encode, for example, informationaccording to the optimal intra prediction mode information supplied fromthe intra prediction section 124 or the optimal inter prediction modesupplied from the motion prediction/compensation section 125, and addsthe encoded information to the encoded data. Further, the losslessencoding section 301 also encodes, for example, the encoded information(syntax) of buffering_period_SEI and layer_buffering_period_SEI suppliedin the process of step S324 according to a certain encoding scheme, andadds the encoded information to the encoded data.

<Flow of Buffering Period SEI Setting Process>

Next, the buffering period SEI encoding process of step S324 of FIG. 38will be described with reference to a flowchart of FIG. 39.

For example, the layer set buffer 312 accumulates the informationrelated to the layer set, and supplies the information related to thelayer set to the layer buffering period SEI setting section 313 at acertain timing.

In step S331, the associated parameter set setting section 311designates an associated parameter set according to the user'soperation. In other words, the user designates which of a VPS (flag=0)and an SPS (flag=1) is associated with buffering_period_SEI.

In step S332, the associated parameter set setting section 311determines whether or not the associated parameter set is a VPS. Whenthe associated parameter set is determined to be a VPS in step S332, theprocess proceeds to step S333.

In step S333, the associated parameter set setting section 311designates a parameter of each layer set. In other words, the associatedparameter set setting section 311 designates a value ofassociated_parameter_set_flag (flag=0), and supplies the designatedvalue to the lossless encoding section 301 and the layer bufferingperiod SEI setting section 313.

At this time, the information related to the layer set stored in the VPSof the enhancement layer image compression information is supplied toand accumulated in the layer set buffer 312 through the losslessencoding section 301. Then, the layer buffering period SEI settingsection 313 sets a parameter of each layer set based on the informationrelated to the layer set supplied from the layer set buffer 312 withreference to the buffer management information supplied from thelossless encoding section 301 (the lower layer) of the base layer imageencoding section 101-1.

Meanwhile, when the associated parameter set is determined not to be aVPS in step S332, the process proceeds to step S334.

In step S334, the associated parameter set setting section 311designates a parameter of a sequence. In other words, the associatedparameter set setting section 311 designates a value ofassociated_parameter_set_flag (flag=1), and supplies the designatedvalue to the lossless encoding section 301 and the layer bufferingperiod SEI setting section 313.

The layer buffering period SEI setting section 313 sets a parameter of asequence with reference to the buffer management information suppliedfrom the lossless encoding section 301 (the lower layer) of the baselayer image encoding section 101-1.

In step S335, the layer parameter transmission designating section 314sets layer_specific_parameters_present_flag according to the user'soperation. In other words, the user designates a value oflayer_specific_parameters_present_flag indicating whether or not settingof a parameter of each layer is performed.

The layer parameter transmission designating section 314 supplies theset value of layer_specific_parameters_present_flag to the losslessencoding section 301 and the layer buffering period SEI setting section313.

In step S336, the layer buffering period SEI setting section 313determines whether or not a value oflayer_specific_parameters_present_flag is 1. When a value oflayer_specific_parameters_present_flag is determined to be 1 in stepS336, the process proceeds to step S337.

In step S337, the layer buffering period SEI setting section 313 sets aparameter of each layer.

Further, when a value of layer_specific_parameters_present_flag isdetermined to be 0 in step S336, the process of step S337 is skipped.

In step S338, the layer buffering period SEI setting section 313 encodesbuffering_period_SEI and layer_buffering_period_SEI including theparameters set as described above, and supplies the encoded informationto the lossless encoding section 301.

Since buffering_period_SEI is associated with a VPS as well as an SPS asdescribed above, when schedule management of an accumulation buffer bybuffering period_SEI is performed, it is possible to manage a layer setas well as a single layer.

Further, since a parameter of each layer is transmitted, it is possibleto perform a schedule management both when all layers included in alayer set are decoded by a single decoding device and when respectivelayers are decoded by separate decoding devices.

<Scalable Decoding Device>

A configuration of a scalable decoding device in the case ofbuffering_period_SEI is basically the same as in the case of the HRDparameter. Thus, an example of a configuration of a scalable decodingdevice in the case of buffering_period_SEI will be described withreference to FIG. 20.

In other words, as in the case of the HRD parameter, the base layerimage decoding section 201-1 is an image decoding section correspondingto the base layer image encoding section 101-1 of FIG. 10, and acquires,for example, the base layer encoded data obtained by encoding the baselayer image information through the base layer image encoding section101-1. The base layer image decoding section 201-1 decodes the baselayer encoded data without referring to other layers, reconstructs thebase layer image information, and outputs the base layer imageinformation.

The enhancement layer image decoding section 201-2 is an image decodingsection corresponding to the enhancement layer image encoding section101-2, and acquires, for example, the enhancement layer encoded dataobtained by encoding the enhancement layer image information through theenhancement layer image encoding section 101-2 as in the case of the HRDparameter. The enhancement layer image decoding section 201-2 decodesthe enhancement layer encoded data. At this time, the enhancement layerimage decoding section 201-2 performs the inter-layer prediction withreference to information related to decoding of the base layer asnecessary.

Further, unlike the case of the HRD parameter, buffering period_SEI ofFIG. 33 and layer_buffering_period_SEI of FIGS. 34 and 35 are added toeach encoded data (bitstream) and transmitted. Unlike the case of theHRD parameter, the enhancement layer image decoding section 201-2acquires information related to an associated parameter set frombuffering_period_SEI, and decodes a parameter of each layer set or aparameter for a sequence according to a parameter set indicated by theacquired information.

Further, unlike the case of the HRD parameter, the enhancement layerimage decoding section 201-2 receiveslayer_specific_parameters_present_flag from layer_buffering_period_SEI,and decodes a parameter of each layer according to a value oflayer_specific_parameters_present_flag. Then, the enhancement layerimage decoding section 201-2 monitors the accumulation buffer based onthe decoded parameters.

Further, in the case of the parameter that is not a parameter of eachlayer, that is, the parameter accumulated from the lower layer, theenhancement layer image decoding section 201-2 monitors the accumulationbuffer with reference to the buffer management information supplied froma lossless decoding section 351 of the base layer image decoding section201-1.

Through the decoding, the enhancement layer image decoding section 201-2decodes the encoded data of the enhancement layer, reconstructs theenhancement layer image information, and outputs the enhancement layerimage information.

As in the case of the HRD parameter, the decoding control section 202controls the decoding process of the layer image decoding sections 201,for example, in view of the reference relation of the layer imagedecoding sections 201.

<Example of a Configuration of Layer Image Decoding Section>

FIG. 40 is a block diagram illustrating an example of a mainconfiguration of the enhancement layer image decoding section 201-2 inthe case of buffering_period_SEI.

The base layer image decoding section 201-1 in the case ofbuffering_period_SEI has basically the same configuration as theenhancement layer image decoding section 201-2 of FIG. 40 except that atype of an image serving as a target is different. For the sake ofdescription, in the example of FIG. 40, a configuration of theenhancement layer image decoding section 201-2 will be described as anexample.

The enhancement layer image decoding section 201-2 of FIG. 40 differsfrom the enhancement layer image decoding section 201-2 of FIG. 21 inthat the lossless decoding section 212 is replaced with the losslessdecoding section 351, the HRD type decoding section 224 is not provided,and a buffering period SEI decoding section 352 is added.

In other words, the enhancement layer image decoding section 201-2includes an accumulation buffer 211, a lossless decoding section 351, aninverse quantization section 213, an inverse orthogonal transformsection 214, an operation section 215, a loop filter 216, a screenreordering buffer 217, and a D/A converting section 218. The enhancementlayer image decoding section 201-2 further includes a frame memory 219,a selecting section 220, an intra prediction section 221, a motionprediction/compensation section 222, and a selecting section 223. Theenhancement layer image decoding section 201-2 further includes thebuffering period SEI decoding section 352.

The accumulation buffer 211 is a receiving section that receives thetransmitted enhancement layer encoded data. Information necessary fordecoding such as the prediction mode information is added to theenhancement layer encoded data. buffering_period_SEI of FIG. 33 andlayer_buffering_period_SEI of FIGS. 34 and 35 are added to theenhancement layer encoded data. The accumulation buffer 211 receives andaccumulates the transmitted enhancement layer encoded data, and suppliesthe encoded data to the lossless decoding section 212 at a certaintiming.

Further, the accumulation buffer 211 receives layer_buffering_period_SEIdecoded information supplied from the buffering period SEI decodingsection 352, and performs buffer management based on thelayer_buffering_period_SEI decoded information.

Like the lossless decoding section 212 of FIG. 21, the lossless decodingsection 351 decodes the information that has been encoded by thelossless encoding section 301 and supplied from the accumulation buffer211 according to a scheme corresponding to the encoding scheme of thelossless encoding section 301. The lossless decoding section 351supplies quantized coefficient data of a differential image obtained bythe decoding to the inverse quantization section 213.

Further, like the lossless decoding section 212, the lossless decodingsection 351 appropriately extracts and acquires the NAL unit includingthe video parameter set (VPS), the sequence parameter set (SPS), thepicture parameter set (PPS), and the like which are included in theenhancement layer encoded data. Like the lossless decoding section 212,the lossless decoding section 351 extracts the information related tothe optimal prediction mode from the information, determines which ofthe intra prediction mode and the inter prediction mode has beenselected as the optimal prediction mode based on the information, andsupplies the information related to the optimal prediction mode to oneof the intra prediction section 221 and the motionprediction/compensation section 222 that corresponds to the modedetermined to have been selected.

In other words, for example, in the enhancement layer image decodingsection 201-2, when the intra prediction mode is selected as the optimalprediction mode, the information related to the optimal prediction modeis supplied to the intra prediction section 221. Further, for example,in the enhancement layer image decoding section 201-2, when the interprediction mode is selected as the optimal prediction mode, theinformation related to the optimal prediction mode is supplied to themotion prediction/compensation section 222.

Further, similarly to the lossless decoding section 212, the losslessdecoding section 351 extracts, for example, information necessary forinverse quantization such as the quantization matrix or the quantizationparameter from the NAL unit or the like, and supplies the extractedinformation to the inverse quantization section 213. Further, unlike thelossless decoding section 212, the lossless decoding section 351 parsesand separates, for example, buffering_period_SEI of FIG. 33 andlayer_buffering_period_SET of FIGS. 34 and 35, and suppliesbuffering_period_SEI of FIG. 33 and layer_buffering_period_SEI of FIGS.34 and 35 to the buffering period SEI decoding section 352.

The buffering period SEI decoding section 352 decodes a parameter ofeach layer set or a parameter for a sequence according toassociated_parameter_set_flag of buffering_period_SEI supplied from thelossless decoding section 351. In other words, when a value ofassociated_parameter_set_flag is 0 (=VPS), the layer buffering periodSEI decoding section 352 receives the parameter of each layer set basedon the information related to the layer set supplied from the layer setbuffer 312. Then, the layer buffering period SEI decoding section 352decodes the received parameter of each layer set with reference to thebase layer buffer management information supplied from the losslessdecoding section (the lower layer) 351 of the base layer image decodingsection 201-1.

Further, when a value of associated_parameter_set_flag is 1 (=SPS), thelayer buffering period SEI setting section 313 receives a parameter fora sequence. Then, the layer buffering period SEI decoding section 352decodes the received parameter for the sequence with reference to thebase layer buffer management information of the lossless decodingsection (the lower layer) 351 of the base layer image decoding section201-1.

Further, the buffering period SEI decoding section 352 receiveslayer_specific_parameters_present_flag of layer_buffering_period_SEIsupplied from the lossless decoding section 351, and receives anddecodes a parameter of each layer according to a value oflayer_specific_parameters_present_flag, that is, when a value oflayer_specific_parameters_present_flag is 1. Then, the layer bufferingperiod SEI decoding section 352 supplies the layer_buffering_period_SEIdecoded information decoded according to associated_parameter_set_flagand layer_specific_parameters_present_flag to the accumulation buffer211.

Further, for example, when there is an enhancement layer image decodingsection 201-3 of an upper layer as indicated by a dotted line, and thereis a request from its buffering period SEI decoding section 352, thelossless decoding section 351 supplies the management information of theaccumulation buffer 211 to the enhancement layer image decoding section201-3 of the upper layer.

<Example of Configuration of Buffering Period SEI Decoding Section>

FIG. 41 is a block diagram illustrating an example of a configuration ofthe buffering period SEI decoding section of FIG. 40.

In an example of FIG. 41, the buffering period SEI decoding section 352is configured to include an associated parameter set decoding section361, a layer set buffer 362, a layer buffering period SEI decodingsection 363, and a layer parameter transmission receiving section 364.

The lossless decoding section 351 parses and separatesbuffering_period_SEI and layer_buffering_period_SEI, and suppliesbuffering_period_SEI encoded information andassociated_parameter_set_flag therein to the associated parameter setdecoding section 361. Further, the lossless decoding section 351supplies layer_buffering_period_SEI encoded information to the layerbuffering period SEI decoding section 363, and supplieslayer_specific_parameters_present_flag therein to the layer parametertransmission receiving section 364.

The associated parameter set decoding section 361 receivesassociated_parameter_set_flag supplies from the lossless decodingsection 351, and analyzes the buffering_period_SEI encoded informationaccording to a value thereof. In other words, the associated parameterset decoding section 361 acquires necessary information from thebuffering_period_SEI encoded information according to a value ofassociated_parameter_set_flag, and supplies the acquired information tothe layer buffering period SEI decoding section 363.

In the case of associated_parameter_set_flag=0, that is, whenbuffering_period_SEI is associated with a VPS, the lossless decodingsection 351 supplies the information related to the layer set stored inthe VPS of the enhancement layer image compression information to thelayer set buffer 362. The layer set buffer 362 accumulates theinformation related to the layer set, and supplies the informationrelated to the layer set to the layer buffering period SEI decodingsection 363 at a certain timing.

The layer buffering period SEI decoding section 363 analyzes thelayer_buffering_period_SEI encoded information according toassociated_parameter_set_flag supplied from the associated parameter setdecoding section 361 with respect to the base layer buffer managementinformation of the lossless decoding section (the lower layer) 351 ofthe base layer image decoding section 201-1. Then, the layer bufferingperiod SEI decoding section 363 decodes the parameter of each layer setor the parameter for the sequence using the analyzed encodedinformation.

In other words, when a value of associated_parameter_set_flag is 1(=VPS), the layer buffering period SEI decoding section 363 decodes theparameter of each layer set based on the information related to thelayer set supplied from the layer set buffer 362. Further, when a valueof associated_parameter_set_flag is 0 (=SPS), the layer buffering periodSEI decoding section 363 decodes the parameter for the sequence.

Further, the layer buffering period SEI decoding section 363 receiveslayer_specific_parameters_present_flag supplied from the layer parametertransmission receiving section 364, and analyzes thelayer_buffering_period_SEI encoded information according to a valuethereof. When a value of layer_specific_parameters_present_flag is 1,the layer buffering period SEI decoding section 363 decodes theparameter of each layer.

Then, the layer buffering period SEI decoding section 363 supplies thelayer_buffering_period_SEI decoded information decoded according toassociated_parameter set_flag and layer_specific_parameters_present_flagto the accumulation buffer 211.

The layer parameter transmission receiving section 364 analyzes a valueof layer_specific_parameters_present_flag, and supplies the analyzedvalue of layer_specific_parameters_present_flag to the layer bufferingperiod SEI decoding section 363.

<Flow of Decoding Process>

Next, the flow of the process performed by the scalable decoding device200 in the case of buffering_period_SEI will be described. The flow ofthe decoding process is basically the same as the flow of the decodingprocess described above with reference to FIG. 23, and thus adescription thereof is omitted.

<Flow of Layer Decoding Process>

Next, the layer decoding process in step S202 of FIG. 23 will bedescribed with reference to a flowchart of FIG. 42. In steps S351 andS354 to S361 of FIG. 42, basically the same processes as in steps S211and S214 to S221 of FIG. 24 are performed, and thus a descriptionthereof is omitted.

In other words, in step S352, the lossless decoding section 351 decodesthe bitstream (the encoded differential image information) of theenhancement layer supplied from the accumulation buffer 211. In otherwords, the I picture, the P picture, and the B picture encoded by thelossless encoding section 301 are decoded. At this time, various kindsof information other than the differential image information included inthe bitstream, such as the header information, are also decoded. Forexample, the lossless decoding section 351 parses and separatesbuffering_period_SEI and layer_buffering_period_SEI, and suppliesbuffering_period_SEI and layer_buffering_period_SEI to the bufferingperiod SEI decoding section 352.

In step S353, the buffering period SEI decoding section 352 performs abuffering period SEI decoding process. The buffering period SEI decodingprocess will be described later with reference to FIG. 43.

layer_buffering_period_SEI is decoded in step S353, and thelayer_buffering_period_SEI decoded information is supplied to theaccumulation buffer 211. Then, the accumulation buffer 211 performs thebuffer management based on the layer_buffering_period_SEI decodedinformation.

<Flow of Buffering Period SEI Decoding Process>

Next, the buffering period SEI decoding process of step S353 of FIG. 42will be described with reference to a flowchart of FIG. 43.

The lossless decoding section 351 parses and separatesbuffering_period_SEI and layer_buffering_period_SEI, and supplies thebuffering_period_SEI encoded information andassociated_parameter_set_flag therein to the associated parameter setdecoding section 361. Further, the lossless decoding section 351supplies the layer_buffering_period_SEI encoded information to the layerbuffering period SEI decoding section 363, and supplieslayer_specific_parameters_present_flag therein to the layer parametertransmission receiving section 364.

In step S371, the associated parameter set decoding section 361 receivesassociated_parameter_set_flag serving as the information related to theassociated parameter set supplied from the lossless decoding section351. In step S372, the associated parameter set decoding section 361determines whether or not the associated parameter set is the VPS withreference to the value of associated_parameter_set_flag supplied fromthe lossless decoding section 351.

When a value of associated_parameter_set_flag is determined to be 0 instep S372, that is, when the associated parameter set is determined tobe the VPS, the process proceeds to step S373. At this time, theassociated parameter set decoding section 361 acquires necessaryinformation (information related to the parameter of each layer set)from the buffering_period_SEI encoded information, and supplies theacquired information to the layer buffering period SEI decoding section363.

In response to this, the layer buffering period SEI decoding section 363analyzes the layer_buffering_period_SEI encoded information according toassociated_parameter_set_flag=1 supplied from the associated parameterset decoding section 361 with reference to the necessary informationobtained from the buffering_period_SEI encoded information and the baselayer buffer management information of the lossless decoding section(the lower layer) 351 of the base layer image decoding section 201-1.Then, in step S373, the layer buffering period SEI decoding section 363decodes the parameter of each layer set using the analyzed encodedinformation. The layer buffering period SEI decoding section 363supplies the layer_buffering_period_SEI decoded information obtained bydecoding the parameter of each layer set to the accumulation buffer 211.

Further, when a value of associated_parameter_set_flag is determined tobe 1 in step S372, that is, when an associated parameter set isdetermined to be the SPS other than the VPS, the process proceeds tostep S374. At this time, the associated parameter set decoding section361 acquires necessary information (information related to the parameterfor the sequence) from the buffering_period_SEI encoded information, andsupplies the acquired information to the layer buffering period SEIdecoding section 363.

In response to this, the layer buffering period SEI decoding section 363analyzes the layer_buffering_period_SEI encoded information according toassociated_parameter_set_flag=0 supplied from the associated parameterset decoding section 361 with reference to the necessary informationobtained from the buffering_period_SEI encoded information and the baselayer buffer management information of the lossless decoding section(the lower layer) 351 of the base layer image decoding section 201-1.Then, in step S374, the layer buffering period SEI decoding section 363decodes the parameter for the sequence using the analyzed encodedinformation. The layer buffering period SEI decoding section 363supplies the layer_buffering_period_SEI decoded information obtained bydecoding the parameter for the sequence to the accumulation buffer 211.

In step S375, the layer parameter transmission receiving section 364receives layer_specific_parameters_present_flag supplied from thelossless decoding section 351. The layer parameter transmissionreceiving section 364 analyzes a value oflayer_specific_parameters_present_flag, and supplies the analyzed valueof layer_specific_parameters_present_flag to the layer buffering periodSEI decoding section 363.

In step S376, the layer buffering period SEI decoding section 363determines whether or not a value oflayer_specific_parameters_present_flag is 1. When a value oflayer_specific_parameters_present_flag is determined to be 1 in stepS376, the process proceeds to step S377.

In step S377, the layer buffering period SEI decoding section 363analyzes the layer_buffering_period_SEI encoded information, and decodesthe parameter of each layer. The layer buffering period SEI decodingsection 363 supplies the layer_buffering period_SEI decoded informationobtained by decoding the parameter of each layer to the accumulationbuffer 211.

Further, when a value of layer_specific_parameters_present_flag isdetermined to be 0 in step S376, step S377 is skipped.

Since buffering_period_SEI is associated with a VPS as well as an SPS asdescribed above, when schedule management of an accumulation buffer bybuffering_period_SEI is performed, it is possible to manage a layer setas well as a single layer.

Further, since a parameter of each layer is transmitted, it is possibleto perform a schedule management both when all layers included in alayer set are decoded by a single decoding device and when respectivelayers are decoded by separate decoding devices.

5. Fifth Embodiment About AVC Flag

Meanwhile, a technique of defining a parameter for the case of ex12 forperforming a decoding process of decoding respective layers including alayer to be referred to through separate decoding devices in addition tothe case of ex11 of performing a decoding process by a single decodingdevice as a parameter for buffer management by hdr_parameters( ) inimage compression information or sub image compression information asdescribed above with reference to FIG. 6 has been proposed.

However, when the base layer (BL) serving as the lower layer is encodedby the AVC and the enhancement layer (EL) serving as the upper layer isencoded by the HEVC, it is difficult to implement an example ofprocessing the BL and the EL by a single decoding device.

In this regard, in Vps_extention( ), avc_base_layer_flag serving as aflag indicating that the base layer is encoded by the AVC istransmitted. Then, when avc_base layer_flag=1, parameter transmission ofthe example of ex11 is prohibited. This is implemented by a semanticrestriction. Hereinafter, avc_base_layer_flag is also referred to as an“AVC flag.”

<HRD Parameter Encoding Process in Case of AVC Flag>

Next, another example of the HRD parameter encoding process of step S124of FIG. 15 will be described with reference to a flowchart of FIG. 44.In steps S413 to S418 of FIG. 44, basically the same processes as insteps S132 to S137 of FIG. 16 are performed, and thus duplicatedescription is omitted.

For example, the lossless encoding section 116 of FIG. 12 suppliesavc_base_layer_flag of Vps_extention to the HRD parameter type settingsection 143.

In step S411, the HRD parameter type setting section 143 checks a valueof avc_base_layer_flag (AVC flag) supplied from the lossless encodingsection 116.

In step S412, the HRD parameter type setting section 143 sets the HRDparameter type. At this time, when a value of avc_base_layer flag (AVCflag) checked in step S411 is 1, it indicates that the base layer isencoded by the AVC, and a process of performing a decoding process of acorresponding layer and a lower layer is prohibited. Thus, the HRDparameter type setting section 143 sets the HRD parameter type to 1serving as a value for performing a decoding process of only acorresponding layer.

When a value of avc_base_layer_flag (AVC flag) checked in step S411 is0, similarly to step S131 of FIG. 16, the HRD parameter type settingsection 143 sets the HRD parameter type according to the user'sinstruction.

The HRD parameter type setting section 143 supplies the flag indicatingthe set HRD parameter type to the lossless encoding section 116 and thelayer HRD parameter calculating section 141.

As described above, in Vps_extention( ), when avc_base layer_flag=1indicating that the base layer is encoded by the AVC, the HRD parametertype is set to 1 serving as a value for performing a decoding process ofonly a corresponding layer. Thus, when the base layer is encoded by theAVC, since a process of performing a decoding process of a correspondinglayer and a lower layer is prohibited at the decoding side, the decodingside is prevented from receiving an illegal bitstream.

The above semantics can be applied even to the case ofbuffering_period_SEI.

<Buffering Period SEI Encoding Process in Case of AVC Flag>

Next, another example of the buffering period SEI encoding process ofstep S324 of FIG. 38 will be described with reference to a flowchart ofFIG. 45. In steps S431 to S434 and steps S437 to S439 of FIG. 45,basically the same processes as in steps S331 to S334 and S336 to S338of FIG. 39 are performed, and thus duplicate description is omitted.

For example, the lossless encoding section 301 of FIG. 37 suppliesavc_base_layer_flag of Vps_extention to the layer parameter transmissiondesignating section 314.

In step S435, the layer parameter transmission designating section 314checks a value of avc_base_layer_flag (AVC flag) supplied from thelossless encoding section 301.

In step S436, the layer parameter transmission designating section 314sets layer_specific_parameters_present_flag. At this time, when a valueof avc_base_layer_flag (AVC flag) checked in step S435 is 1, itindicates that the base layer is encoded by the AVC, and a process ofperforming a decoding process of a corresponding layer and a lower layeris prohibited. Thus, the layer parameter transmission designatingsection 314 sets layer_specific_parameters_present_flag to 1 serving asa value indicating that a parameter of each layer is set. Further, whenlayer_specific_parameters_present_flag=1, a parameter accumulated from alower layer may not be set.

When a value of avc_base_layer flag (AVC flag) checked in step S435 is0, similarly to step S335 of FIG. 39, the layer parameter transmissiondesignating section 314 sets layer_specific_parameters_present_flagaccording to the user's operation.

The layer parameter transmission designating section 314 supplies theset value of layer_specific_parameters_present_flag to the losslessencoding section 301 and the layer buffering period SEI setting section313. Further, the buffer management information in the base layer issupplied from the lossless encoding section 301 of the base layer imageencoding section 101-1 to the layer buffering period SEI setting section313.

As described above, in Vps_extention( ), when avc_base_layer flag=1,layer_specific_parameters_present_flag is set to 1 serving as a valueindicating that a parameter of each layer is set. Thus, when the baselayer is encoded by the AVC, since a process of performing a decodingprocess of a corresponding layer and a lower layer is prohibited at thedecoding side, the decoding side is prevented from receiving an illegalbitstream.

Although the example in which image data is hierarchized into aplurality of layers by scalable video coding has been described above,the number of layers is arbitrary. For example, some pictures may behierarchized. Further, although the example in which the enhancementlayer is processed with reference to the base layer at the time ofencoding and decoding has been described above, the present technologyis not limited to this example, and the enhancement layer may beprocessed with reference to any other processed enhancement layer.

Further, a view in multi-view image encoding and decoding is alsoincluded as a layer described above. In other words, the presenttechnology can be applied to multi-view image encoding and multi-viewimage decoding. FIG. 46 illustrates an example of a multi-view imageencoding scheme.

6. Sixth Embodiment Application to Multi-View Image Encoding andMulti-View Image Decoding

The above-described series of processes can be applied to multi-viewimage encoding and multi-view image decoding. FIG. 46 illustrates anexample of a multi-view image encoding scheme.

As illustrated in FIG. 46, a multi-view image includes images of aplurality of views. A plurality of views of the multi-view imageincludes a base view in which encoding and decoding are performed usingan image of its own view without using an image of another view and anon-base view in which encoding and decoding are performed using animage of another view. As a non-base view, an image of a base view maybe used, and an image of another non-base view may be used.

When the multi-view image of FIG. 46 is encoded or decoded, an image ofeach view is encoded or decoded, but the methods according to the firstand second embodiments may be applied to encoding or decoding of eachview. As a result, it is possible to perform a decoding process at aproper timing.

Further, the flags or the parameters used in the methods according tothe first and second embodiments may be shared in encoding and decodingof each view. As a result, it is possible to suppress transmission ofredundant information and reduce an amount of information to betransmitted (a coding amount) (that is, it is possible to suppress areduction in encoding efficiency).

More specifically, for example, the HRD parameter type flag, the HRDparameter, or buffering_period_SEI and layer_buffering_period_SEI may beshared in encoding and decoding of each view.

Of course, any other necessary information may also be shared inencoding and decoding of each view.

[Multi-View Image Encoding Device]

FIG. 47 is a diagram illustrating a multi-view image encoding devicewhich performs the above-described multi-view image encoding. Asillustrated in FIG. 47, the multi-view image encoding device 600 has anencoding section 601, an encoding section 602, and a multiplexingsection 603.

The encoding section 601 encodes a base view image and generates a baseview image encoded stream. The encoding section 602 encodes a non-baseview image and generates a non-base view image encoded stream. Themultiplexing section 603 multiplexes the base view image encoded streamgenerated in the encoding section 601 and the non-base view imageencoded stream generated in the encoding section 602, and generates amulti-view image encoded stream.

The scalable encoding device 100 (FIG. 10) can be applied to theencoding section 601 and the encoding section 602 of the multi-viewimage encoding device 600. In other words, it is possible to set the HRDparameter type flag or the HRD parameter for each view in encoding ofeach view, and it is possible to perform a decoding process at a propertiming. Further, since the encoding section 601 and the encoding section602 can use the same HRD parameter type flag or the same HRD parameter(that is, can share the flag or the parameter), it is possible tosuppress a reduction in encoding efficiency, and it is possible toperform a decoding process at a proper timing. Furthermore, since thesame applies to buffering_period_SEI and layer_buffering_period_SEI, itis similarly possible to suppress a reduction in encoding efficiency,and it is possible to perform a decoding process at a proper timing.

[Configuration Example of Multi-View Image Decoding Device]

FIG. 48 is a diagram illustrating the multi-view image decoding devicefor performing the above-described multi-view image decoding. Asillustrated in FIG. 39, the multi-view image decoding device 610 has aninverse multiplexing section 611, a decoding section 612, and a decodingsection 613.

The inverse multiplexing section 611 inversely multiplexes a multi-viewimage encoded stream in which a base view image encoded stream and anon-base view image encoded stream are multiplexed, and extracts thebase view image encoded stream and the non-base view image encodedstream. The decoding section 612 decodes the base view image encodedstream extracted by the inverse multiplexing section 611 and obtains abase view image. The decoding section 613 decodes the non-base viewimage encoded stream extracted by the inverse multiplexing section 611and obtains a non-base view image.

The scalable decoding device 200 (FIG. 20) can be applied to thedecoding section 612 and the decoding section 613 of the multi-viewimage decoding device 610. In other words, it is possible to set the HRDparameter type flag or the HRD parameter for each view in encoding ofeach view, and it is possible to perform a decoding process at a propertiming. Further, since the decoding section 612 and the decoding section613 can use the same HRD parameter type flag or the same HRD parameter(that is, can share the flag or the parameter), it is possible tosuppress a reduction in encoding efficiency, and it is possible toperform a decoding process at a proper timing. Furthermore, since thesame applies to buffering_period_SEI and layer_buffering_period_SEI, itis similarly possible to suppress a reduction in encoding efficiency,and it is possible to perform a decoding process at a proper timing.

As described above, the present technology can be applied to all imageencoding devices and all image decoding devices based on scalableencoding and decoding.

For example, the present technology can be applied to an image encodingdevice and an image decoding device used when image information(bitstream) compressed by an orthogonal transform such as a discretecosine transform and motion compensation as in MPEG and H.26x isreceived via a network medium such as satellite broadcasting, cabletelevision, the Internet, or a mobile telephone. Further, the presenttechnology can be applied to an image encoding device and an imagedecoding device used when processing is performed on a storage mediumsuch as an optical disc, a magnetic disk, or a flash memory.Furthermore, the present technology can be applied even to an orthogonaltransform device or an inverse orthogonal transform device equipped inthe image encoding device, the image decoding device, or the like.

7. Seventh Embodiment Computer

The above described series of processes can be executed by hardware orcan be executed by software. When the series of processes are to beperformed by software, the programs forming the software are installedinto a computer. Here, a computer includes a computer which isincorporated in dedicated hardware or a general-purpose personalcomputer (PC) which can execute various functions by installing variousprograms into the computer, for example.

FIG. 49 is a block diagram illustrating a configuration example ofhardware of a computer for executing the above-described series ofprocesses through a program.

In a computer 800 shown in FIG. 49, a central processing unit (CPU) 801,a read only memory (ROM) 802, and a random access memory (RAM) 803 areconnected to one another by a bus 804.

An input and output interface (I/F) 810 is further connected to the bus804. An input section 811, an output section 812, a storage section 813,a communication section 814, and a drive 815 are connected to the inputand output I/F 810.

The input section 811 is formed with a keyboard, a mouse, a microphone,a touch panel, an input terminal, and the like. The output section 812is formed with a display, a speaker, an output terminal, and the like.The storage section 813 is formed with a hard disk, a nonvolatilememory, or the like. The communication section 814 is formed with anetwork interface or the like. The drive 815 drives a removable medium821 such as a magnetic disk, an optical disk, a magneto-optical disk, ora semiconductor memory.

In the computer configured as described above, the CPU 801 loads theprograms stored in the storage section 813 into the RAM 803 via theinput and output I/F 810 and the bus 804, and executes the programs, sothat the above described series of processes are performed. The RAM 803also stores data necessary for the CPU 801 to execute the variousprocesses.

The program executed by the computer 800 (the CPU 801) may be providedby being recorded on the removable medium 821 as a packaged medium orthe like. The program can also be applied via a wired or wirelesstransfer medium, such as a local area network, the Internet, or adigital satellite broadcast.

In the computer, by loading the removable medium 821 into the drive 815,the program can be installed into the storage section 813 via the inputand output I/F 810. It is also possible to receive the program from awired or wireless transfer medium using the communication section 814and install the program into the storage section 813. As anotheralternative, the program can be installed in advance into the ROM 802 orthe storage section 813.

It should be noted that the program executed by a computer may be aprogram that is processed in time series according to the sequencedescribed in this specification or a program that is processed inparallel or at necessary timing such as upon calling.

In the present disclosure, steps of describing the program to berecorded on the recording medium may include processing performed intime-series according to the description order and processing notprocessed in time-series but performed in parallel or individually.

In addition, in this disclosure, a system means a set of a plurality ofelements (devices, modules (parts), or the like) regardless of whetheror not all elements are arranged in a single housing. Thus, both aplurality of devices that are accommodated in separate housings andconnected via a network and a single device in which a plurality ofmodules are accommodated in a single housing are systems.

Further, an element described as a single device (or processing unit)above may be divided and configured as a plurality of devices (orprocessing units). On the contrary, elements described as a plurality ofdevices (or processing units) above may be configured collectively as asingle device (or processing unit). Further, an element other than thosedescribed above may be added to each device (or processing unit).Furthermore, a part of an element of a given device (or processing unit)may be included in an element of another device (or another processingunit) as long as the configuration or operation of the system as a wholeis substantially the same.

The preferred embodiments of the present disclosure have been describedabove with reference to the accompanying drawings, whilst the presentinvention is not limited to the above examples, of course. A personskilled in the art may find various alterations and modifications withinthe scope of the appended claims, and it should be understood that theywill naturally come under the technical scope of the present disclosure.

For example, the present disclosure can adopt a configuration of cloudcomputing which processes by allocating and connecting one function by aplurality of apparatuses through a network.

Further, each step described by the above mentioned flow charts can beexecuted by one apparatus or by allocating a plurality of apparatuses.

In addition, in the case where a plurality of processes is included inone step, the plurality of processes included in this one step can beexecuted by one apparatus or by allocating a plurality of apparatuses.

The image encoding device and the image decoding device according to theembodiment may be applied to various electronic devices such astransmitters and receivers for satellite broadcasting, cablebroadcasting such as cable TV, distribution on the Internet,distribution to terminals via cellular communication and the like,recording devices that record images in a medium such as optical discs,magnetic disks and flash memory, and reproduction devices that reproduceimages from such storage medium. Four applications will be describedbelow.

8. Applications First Application: Television Receivers

FIG. 50 illustrates an example of a schematic configuration of atelevision device to which the embodiment is applied. A televisiondevice 900 includes an antenna 901, a tuner 902, a demultiplexer 903, adecoder 904, an video signal processing section 905, a display section906, an audio signal processing section 907, a speaker 908, an externalI/F 909, a control section 910, a user I/F 911, and a bus 912.

The tuner 902 extracts a signal of a desired channel from broadcastsignals received via the antenna 901, and demodulates the extractedsignal. The tuner 902 then outputs an encoded bitstream obtained throughthe demodulation to the demultiplexer 903. That is, the tuner 902 servesas a transmission unit of the television device 900 for receiving anencoded stream in which an image is encoded.

The demultiplexer 903 demultiplexes the encoded bitstream to obtain avideo stream and an audio stream of a program to be viewed, and outputseach stream obtained through the demultiplexing to the decoder 904. Thedemultiplexer 903 also extracts auxiliary data such as electronicprogram guides (EPGs) from the encoded bitstream, and supplies theextracted data to the control section 910. Additionally, thedemultiplexer 903 may perform descrambling when the encoded bitstreamhas been scrambled.

The decoder 904 decodes the video stream and the audio stream input fromthe demultiplexer 903. The decoder 904 then outputs video data generatedin the decoding process to the video signal processing section 905. Thedecoder 904 also outputs the audio data generated in the decodingprocess to the audio signal processing section 907.

The video signal processing section 905 reproduces the video data inputfrom the decoder 904, and causes the display section 906 to display thevideo. The video signal processing section 905 may also cause thedisplay section 906 to display an application screen supplied via anetwork. Further, the video signal processing section 905 may perform anadditional process such as noise removal, for example, on the video datain accordance with the setting. Furthermore, the video signal processingsection 905 may generate an image of a graphical user I/F (GUI) such asa menu, a button and a cursor, and superimpose the generated image on anoutput image.

The display section 906 is driven by a drive signal supplied from thevideo signal processing section 905, and displays a video or an image ona video screen of a display device (e.g. liquid crystal display, plasmadisplay, organic electroluminescence display (OLED), etc.).

The audio signal processing section 907 performs a reproduction processsuch as D/A conversion and amplification on the audio data input fromthe decoder 904, and outputs a sound from the speaker 908. The audiosignal processing section 907 may also perform an additional processsuch as noise removal on the audio data.

The external I/F 909 is an I/F for connecting the television device 900to an external device or a network. For example, a video stream or anaudio stream received via the external I/F 909 may be decoded by thedecoder 904. That is, the external I/F 909 also serves as a transmissionunit of the television device 900 for receiving an encoded stream inwhich an image is encoded.

The control section 910 includes a processor such as a centralprocessing unit (CPU), and a memory such as random access memory (RAM)and read only memory (ROM). The memory stores a program to be executedby the CPU, program data, EPG data, data acquired via a network, and thelike. The program stored in the memory is read out and executed by theCPU at the time of activation of the television device 900, for example.The CPU controls the operation of the television device 900, forexample, in accordance with an operation signal input from the user I/F911 by executing the program.

The user I/F 911 is connected to the control section 910. The user I/F911 includes, for example, a button and a switch used for a user tooperate the television device 900, and a receiving section for a remotecontrol signal. The user I/F 911 detects an operation of a user viathese structural elements, generates an operation signal, and outputsthe generated operation signal to the control section 910.

The bus 912 connects the tuner 902, the demultiplexer 903, the decoder904, the video signal processing section 905, the audio signalprocessing section 907, the external I/F 909, and the control section910 to each other.

The decoder 904 has a function of the scalable decoding device 200according to the embodiment in the television device 900 configured inthis manner. Thus, when an image is decoded in the television device900, it is possible to perform a decoding process at a proper timing.

Second Application: Mobile Phones

FIG. 51 illustrates an example of a schematic configuration of a mobilephone to which the embodiment is applied. A mobile phone 920 includes anantenna 921, a communication section 922, an audio codec 923, a speaker924, a microphone 925, a camera section 926, an image processing section927, a demultiplexing section 928, a recording/reproduction section 929,a display section 930, a control section 931, an operation section 932,and a bus 933.

The antenna 921 is connected to the communication section 922. Thespeaker 924 and the microphone 925 are connected to the audio codec 923.The operation section 932 is connected to the control section 931. Thebus 933 connects the communication section 922, the audio codec 923, thecamera section 926, the image processing section 927, the demultiplexingsection 928, the recording/reproduction section 929, the display section930, and the control section 931 to each other.

The mobile phone 920 performs an operation such as transmission andreception of an audio signal, transmission and reception of email orimage data, image capturing, and recording of data in various operationmodes including an audio call mode, a data communication mode, an imagecapturing mode, and a videophone mode.

An analogue audio signal generated by the microphone 925 is supplied tothe audio codec 923 in the audio call mode. The audio codec 923 convertsthe analogue audio signal into audio data, has the converted audio datasubjected to the A/D conversion, and compresses the converted data. Theaudio codec 923 then outputs the compressed audio data to thecommunication section 922. The communication section 922 encodes andmodulates the audio data, and generates a transmission signal. Thecommunication section 922 then transmits the generated transmissionsignal to a base station (not illustrated) via the antenna 921. Thecommunication section 922 also amplifies a wireless signal received viathe antenna 921 and converts the frequency of the wireless signal toacquire a received signal. The communication section 922 thendemodulates and decodes the received signal, generates audio data, andoutputs the generated audio data to the audio codec 923. The audio codec923 extends the audio data, has the audio data subjected to the D/Aconversion, and generates an analogue audio signal. The audio codec 923then supplies the generated audio signal to the speaker 924 to output asound.

The control section 931 also generates text data in accordance with anoperation made by a user via the operation section 932, the text data,for example, composing email. Moreover, the control section 931 causesthe display section 930 to display the text. Furthermore, the controlsection 931 generates email data in accordance with a transmissioninstruction from a user via the operation section 932, and outputs thegenerated email data to the communication section 922. The communicationsection 922 encodes and modulates the email data, and generates atransmission signal. The communication section 922 then transmits thegenerated transmission signal to a base station (not illustrated) viathe antenna 921. The communication section 922 also amplifies a wirelesssignal received via the antenna 921 and converts the frequency of thewireless signal to acquire a received signal. The communication section922 then demodulates and decodes the received signal to restore theemail data, and outputs the restored email data to the control section931. The control section 931 causes the display section 930 to displaythe content of the email, and also causes the storage medium of therecording/reproduction section 929 to store the email data.

The recording/reproduction section 929 includes a readable and writablestorage medium. For example, the storage medium may be a built-instorage medium such as RAM and flash memory, or an externally mountedstorage medium such as hard disks, magnetic disks, magneto-opticaldisks, optical discs, universal serial bus (USB) memory, and memorycards.

Furthermore, the camera section 926, for example, captures an image of asubject to generate image data, and outputs the generated image data tothe image processing section 927 in the image capturing mode. The imageprocessing section 927 encodes the image data input from the camerasection 926, and causes the storage medium of the storage/reproductionsection 929 to store the encoded stream.

Furthermore, the demultiplexing section 928, for example, multiplexes avideo stream encoded by the image processing section 927 and an audiostream input from the audio codec 923, and outputs the multiplexedstream to the communication section 922 in the videophone mode. Thecommunication section 922 encodes and modulates the stream, andgenerates a transmission signal. The communication section 922 thentransmits the generated transmission signal to a base station (notillustrated) via the antenna 921. The communication section 922 alsoamplifies a wireless signal received via the antenna 921 and convertsthe frequency of the wireless signal to acquire a received signal. Thesetransmission signal and received signal may include an encodedbitstream. The communication section 922 then demodulates and decodesthe received signal to restore the stream, and outputs the restoredstream to the demultiplexing section 928. The demultiplexing section 928demultiplexes the input stream to obtain a video stream and an audiostream, and outputs the video stream to the image processing section 927and the audio stream to the audio codec 923. The image processingsection 927 decodes the video stream, and generates video data. Thevideo data is supplied to the display section 930, and a series ofimages is displayed by the display section 930. The audio codec 923extends the audio stream, has the audio stream subjected to the D/Aconversion, and generates an analogue audio signal. The audio codec 923then supplies the generated audio signal to the speaker 924, and causesa sound to be output.

The image processing section 927 has functions of the scalable encodingdevice 100 and the scalable decoding device 200 according to theembodiment in the mobile phone 920 configured in this manner. Thus, whenan image is encoded or decoded in the mobile phone 920, it is possibleto perform a decoding process at a proper timing.

Third Application: Recording/Reproduction Device

FIG. 52 illustrates an example of a schematic configuration of arecording/reproduction device to which the embodiment is applied. Arecording/reproduction device 940, for example, encodes audio data andvideo data of a received broadcast program and records the encoded audiodata and the encoded video data in a recording medium. For example, therecording/reproduction device 940 may also encode audio data and videodata acquired from another device and record the encoded audio data andthe encoded video data in a recording medium. Furthermore, therecording/reproduction device 940, for example, uses a monitor or aspeaker to reproduce the data recorded in the recording medium inaccordance with an instruction of a user. At this time, therecording/reproduction device 940 decodes the audio data and the videodata.

The recording/reproduction device 940 includes a tuner 941, an externalI/F 942, an encoder 943, a hard disk drive (HDD) 944, a disc drive 945,a selector 946, a decoder 947, an on-screen display (OSD) 948, a controlsection 949, and a user I/F 950.

The tuner 941 extracts a signal of a desired channel from broadcastsignals received via an antenna (not shown), and demodulates theextracted signal. The tuner 941 then outputs an encoded bitstreamobtained through the demodulation to the selector 946. That is, thetuner 941 serves as a transmission unit of the recording/reproductiondevice 940.

The external I/F 942 is an I/F for connecting the recording/reproductiondevice 940 to an external device or a network. For example, the externalI/F 942 may be an Institute of Electrical and Electronics Engineers(IEEE) 1394 I/F, a network I/F, an USB I/F, a flash memory I/F, or thelike. For example, video data and audio data received via the externalI/F 942 are input to the encoder 943. That is, the external I/F 942serves as a transmission unit of the recording/reproduction device 940.

When the video data and the audio data input from the external I/F 942have not been encoded, the encoder 943 encodes the video data and theaudio data. The encoder 943 then outputs an encoded bitstream to theselector 946.

The HDD 944 records, in an internal hard disk, the encoded bitstream inwhich content data of a video and a sound is compressed, variousprograms, and other pieces of data. The HDD 944 also reads out thesepieces of data from the hard disk at the time of reproducing a video ora sound.

The disc drive 945 records and reads out data in a recording medium thatis mounted. The recording medium that is mounted on the disc drive 945may be, for example, a DVD disc (DVD-Video, DVD-RAM, DVD-R, DVD-RW, aDVD+R, DVD+RW, etc.), a Blu-ray (registered trademark) disc, or thelike.

The selector 946 selects, at the time of recording a video or a sound,an encoded bitstream input from the tuner 941 or the encoder 943, andoutputs the selected encoded bitstream to the HDD 944 or the disc drive945. The selector 946 also outputs, at the time of reproducing a videoor a sound, an encoded bitstream input from the HDD 944 or the discdrive 945 to the decoder 947.

The decoder 947 decodes the encoded bitstream, and generates video dataand audio data. The decoder 947 then outputs the generated video data tothe OSD 948. The decoder 904 also outputs the generated audio data to anexternal speaker.

The OSD 948 reproduces the video data input from the decoder 947, anddisplays a video. The OSD 948 may also superimpose an image of a GUIsuch as a menu, a button, and a cursor on a displayed video.

The control section 949 includes a processor such as a CPU, and a memorysuch as RAM and ROM. The memory stores a program to be executed by theCPU, program data, and the like. For example, a program stored in thememory is read out and executed by the CPU at the time of activation ofthe recording/reproduction device 940. The CPU controls the operation ofthe recording/reproduction device 940, for example, in accordance withan operation signal input from the user I/F 950 by executing theprogram.

The user I/F 950 is connected to the control section 949. The user I/F950 includes, for example, a button and a switch used for a user tooperate the recording/reproduction device 940, and a receiving sectionfor a remote control signal. The user I/F 950 detects an operation madeby a user via these structural elements, generates an operation signal,and outputs the generated operation signal to the control section 949.

The encoder 943 has a function of the scalable encoding device 100according to the embodiment in the recording/reproduction device 940configured in this manner. The decoder 947 also has a function of thescalable decoding device 200 according to the embodiment. Thus, when animage is encoded or decoded in the recording/reproduction device 940, itis possible to perform a decoding process at a proper timing.

Fourth Application: Image Capturing Device

FIG. 53 illustrates an example of a schematic configuration of an imagecapturing device to which the embodiment is applied. An image capturingdevice 960 captures an image of a subject to generate an image, encodesthe image data, and records the image data in a recording medium.

The image capturing device 960 includes an optical block 961, an imagecapturing section 962, a signal processing section 963, an imageprocessing section 964, a display section 965, an external I/F 966, amemory 967, a media drive 968, an OSD 969, a control section 970, a userI/F 971, and a bus 972.

The optical block 961 is connected to the image capturing section 962.The image capturing section 962 is connected to the signal processingsection 963. The display section 965 is connected to the imageprocessing section 964. The user I/F 971 is connected to the controlsection 970. The bus 972 connects the image processing section 964, theexternal I/F 966, the memory 967, the media drive 968, the OSD 969, andthe control section 970 to each other.

The optical block 961 includes a focus lens, an aperture stop mechanism,and the like. The optical block 961 forms an optical image of a subjecton an image capturing surface of the image capturing section 962. Theimage capturing section 962 includes an image sensor such as a chargecoupled device (CCD) and a complementary metal oxide semiconductor(CMOS), and converts the optical image formed on the image capturingsurface into an image signal which is an electrical signal throughphotoelectric conversion. The image capturing section 962 then outputsthe image signal to the signal processing section 963.

The signal processing section 963 performs various camera signalprocesses such as knee correction, gamma correction, and colorcorrection on the image signal input from the image capturing section962. The signal processing section 963 outputs the image data subjectedto the camera signal process to the image processing section 964.

The image processing section 964 encodes the image data input from thesignal processing section 963, and generates encoded data. The imageprocessing section 964 then outputs the generated encoded data to theexternal I/F 966 or the media drive 968. The image processing section964 also decodes encoded data input from the external I/F 966 or themedia drive 968, and generates image data. The image processing section964 then outputs the generated image data to the display section 965.The image processing section 964 may also output the image data inputfrom the signal processing section 963 to the display section 965, andcause the image to be displayed. Furthermore, the image processingsection 964 may superimpose data for display acquired from the OSD 969on an image to be output to the display section 965.

The OSD 969 generates an image of a GUI such as a menu, a button, and acursor, and outputs the generated image to the image processing section964.

The external I/F 966 is configured, for example, as an USB input andoutput terminal. The external I/F 966 connects the image capturingdevice 960 and a printer, for example, at the time of printing an image.A drive is further connected to the external I/F 966 as needed. Aremovable medium such as magnetic disks and optical discs is mounted onthe drive, and a program read out from the removable medium may beinstalled in the image capturing device 960. Furthermore, the externalI/F 966 may be configured as a network IF to be connected to a networksuch as a LAN and the Internet. That is, the external I/F 966 serves asa transmission unit of the image capturing device 960.

A recording medium to be mounted on the media drive 968 may be areadable and writable removable medium such as magnetic disks,magneto-optical disks, optical discs, and semiconductor memory. Therecording medium may also be fixedly mounted on the media drive 968,configuring a non-transportable storage section such as built-in harddisk drives or a solid state drives (SSDs).

The control section 970 includes a processor such as a CPU, and a memorysuch as RAM and ROM. The memory stores a program to be executed by theCPU, program data, and the like. A program stored in the memory is readout and executed by the CPU, for example, at the time of activation ofthe image capturing device 960. The CPU controls the operation of theimage capturing device 960, for example, in accordance with an operationsignal input from the user I/F 971 by executing the program.

The user I/F 971 is connected to the control section 970. The user I/F971 includes, for example, a button, a switch, and the like used for auser to operate the image capturing device 960. The user I/F 971 detectsan operation made by a user via these structural elements, generates anoperation signal, and outputs the generated operation signal to thecontrol section 970.

The image processing section 964 has a function of the scalable encodingdevice 100 and the scalable decoding device 200 according to theembodiment in the image capturing device 960 configured in this manner.Thus, when an image is encoded is decoded in the image capturing device960, it is possible to perform a decoding process at a proper timing.

9. Application Example of Scalable Video Coding First System

Next, a specific example of using scalable encoded data, in which ascalable video coding (hierarchical coding) is performed, will bedescribed. The scalable video coding, for example, is used for selectionof data to be transmitted as examples illustrated in FIG. 54.

In a data transmission system 1000 illustrated in FIG. 54, adistribution server 1002 reads scalable encoded data stored in ascalable encoded data storage section 1001, and distributes the scalableencoded data to a terminal device such as a PC 1004, an AV device 1005,a tablet device 1006, or a mobile phone 1007 via a network 1003.

At this time, the distribution server 1002 selects and transmits encodeddata having proper quality according to capability of the terminaldevice, communication environment, or the like. Even when thedistribution server 1002 transmits unnecessarily high-quality data, ahigh-quality image is not necessarily obtainable in the terminal deviceand it may be a cause of occurrence of a delay or an overflow. Inaddition, a communication band may be unnecessarily occupied or a loadof the terminal device may be unnecessarily increased. In contrast, evenwhen the distribution server 1002 transmits unnecessarily low qualitydata, an image with a sufficient quality may not be obtained. Thus, thedistribution server 1002 appropriately reads and transmits the scalableencoded data stored in the scalable encoded data storage section 1001 asthe encoded data having a proper quality according to the capability ofthe terminal device, the communication environment, or the like.

For example, the scalable encoded data storage section 1001 isconfigured to store scalable encoded data (BL+EL) 1011 in which thescalable video coding is performed. The scalable encoded data (BL+EL)1011 is encoded data including both a base layer and an enhancementlayer, and is data from which a base layer image and an enhancementlayer image can be obtained by performing decoding.

The distribution server 1002 selects an appropriate layer according tothe capability of the terminal device for transmitting data, thecommunication environment, or the like, and reads the data of theselected layer. For example, with respect to the PC 1004 or the tabletdevice 1006 having high processing capability, the distribution server1002 reads the scalable encoded data (BL+EL) 1011 from the scalableencoded data storage section 1001, and transmits the scalable encodeddata (BL+EL) 1011 without change. On the other hand, for example, withrespect to the AV device 1005 or the mobile phone 1007 having lowprocessing capability, the distribution server 1002 extracts the data ofthe base layer from the scalable encoded data (BL+EL) 1011, andtransmits the extracted data of the base layer as low quality scalableencoded data (BL) 1012 that is data having the same content as thescalable encoded data (BL+EL) 1011 but has lower quality than thescalable encoded data (BL+EL) 1011.

Because an amount of data can easily be adjusted by employing thescalable encoded data, the occurrence of the delay or the overflow canbe suppressed or the unnecessary increase of the load of the terminaldevice or the communication media can be suppressed. In addition,because a redundancy between the layers is reduced in the scalableencoded data (BL+EL) 1011, it is possible to further reduce the amountof data than when the encoded data of each layer is treated as theindividual data. Therefore, it is possible to more efficiently use thestorage region of the scalable encoded data storage section 1001.

Because various devices such as the PC 1004 to the mobile phone 1007 areapplicable as the terminal device, the hardware performance of theterminal devices differs according to the device. In addition, becausethere are various applications which are executed by the terminaldevice, the software performance thereof also varies. Further, becauseall the communication networks including a wired, wireless, or both suchas the Internet and the local area network (LAN) are applicable as thenetwork 1003 serving as a communication medium, the data transmissionperformance thereof varies. Further, the data transmission performancemay vary by other communications, or the like.

Therefore, the distribution server 1002 may perform communication withthe terminal device which is the data transmission destination beforestarting the data transmission, and then obtain information related tothe terminal device performance such as hardware performance of theterminal device, or the application (software) performance which isexecuted by the terminal device, and information related to thecommunication environment such as an available bandwidth of the network1003. Then, distribution server 1002 may select an appropriate layerbased on the obtained information.

Also, the extraction of the layer may be performed in the terminaldevice. For example, the PC 1004 may decode the transmitted scalableencoded data (BL+EL) 1011 and display the image of the base layer ordisplay the image of the enhancement layer. In addition, for example,the PC 1004 may be configured to extract the scalable encoded data (BL)1012 of the base layer from the transmitted scalable encoded data(BL+EL) 1011, store the extracted scalable encoded data (BL) 1012 of thebase layer, transmit to another device, or decode and display the imageof the base layer.

Of course, the number of the scalable encoded data storage sections1001, the distribution servers 1002, the networks 1003, and the terminaldevices are optional. In addition, although the example of thedistribution server 1002 transmitting the data to the terminal device isdescribed above, the example of use is not limited thereto. The datatransmission system 1000 is applicable to any system which selects andtransmits an appropriate layer according to the capability of theterminal device, the communication environment, or the like when thescalable encoded data is transmitted to the terminal device.

Second System

In addition, the scalable video coding, for example, is used fortransmission via a plurality of communication media as in an exampleillustrated in FIG. 55.

In a data transmission system 1100 illustrated in FIG. 55, abroadcasting station 1101 transmits scalable encoded data (BL) 1121 ofthe base layer by terrestrial broadcasting 1111. In addition, thebroadcasting station 1101 transmits scalable encoded data (EL) 1122 ofthe enhancement layer via any arbitrary network 1112 made of acommunication network that is wired, wireless, or both (for example, thedata is packetized and transmitted).

A terminal device 1102 has a function of receiving the terrestrialbroadcasting 1111 that is broadcast by the broadcasting station 1101 andreceives the scalable encoded data (BL) 1121 of the base layertransmitted via the terrestrial broadcasting 1111. In addition, theterminal device 1102 further has a communication function by which thecommunication is performed via the network 1112, and receives thescalable encoded data (EL) 1122 of the enhancement layer transmitted viathe network 1112.

For example, according to a user's instruction or the like, the terminaldevice 1102 decodes the scalable encoded data (BL) 1121 of the baselayer acquired via the terrestrial broadcasting 1111, thereby obtainingor storing the image of the base layer or transmitting the image of thebase layer to other devices.

In addition, for example, according to the user's instruction, theterminal device 1102 combines the scalable encoded data (BL) 1121 of thebase layer acquired via the terrestrial broadcasting 1111 and thescalable encoded data (EL) 1122 of the enhancement layer acquired viathe network 1112, thereby obtaining the scalable encoded data (BL+EL),obtaining or storing the image of the enhancement layer by decoding thescalable encoded data (BL+EL), or transmitting the image of theenhancement layer to other devices.

As described above, the scalable encoded data, for example, can betransmitted via the different communication medium for each layer.Therefore, it is possible to disperse the load and suppress theoccurrence of the delay or the overflow.

In addition, according to the situation, the communication medium usedfor the transmission for each layer may be configured to be selected.For example, the scalable encoded data (BL) 1121 of the base layer inwhich the amount of data is comparatively large may be transmitted viathe communication medium having a wide bandwidth, and the scalableencoded data (EL) 1122 of the enhancement layer in which the amount ofdata is comparatively small may be transmitted via the communicationmedia having a narrow bandwidth. In addition, for example, whether thecommunication medium that transmits the scalable encoded data (EL) 1122of the enhancement layer is the network 1112 or the terrestrialbroadcasting 1111 may be switched according to the available bandwidthof the network 1112. Of course, the same is true for data of anarbitrary layer.

By controlling in this way, it is possible to further suppress theincrease of the load in the data transmission.

Of course, the number of the layers is optional, and the number ofcommunication media used in the transmission is also optional. Inaddition, the number of terminal devices 1102 which are the destinationof the data distribution is also optional. Further, although the exampleof the broadcasting from the broadcasting station 1101 has beendescribed above, the use example is not limited thereto. The datatransmission system 1100 can be applied to any system which divides thescalable encoded data using a layer as a unit and transmits the scalableencoded data via a plurality of links.

Third System

In addition, the scalable video coding is used in the storage of theencoded data as an example illustrated in FIG. 56.

In an image capturing system 1200 illustrated in FIG. 56, an imagecapturing device 1201 performs scalable video coding on image dataobtained by capturing an image of a subject 1211, and supplies ascalable video result as the scalable encoded data (BL+EL) 1221 to ascalable encoded data storage device 1202.

The scalable encoded data storage device 1202 stores the scalableencoded data (BL+EL) 1221 supplied from the image capturing device 1201in quality according to the situation. For example, in the case ofnormal circumstances, the scalable encoded data storage device 1202extracts data of the base layer from the scalable encoded data (BL+EL)1221, and stores the extracted data as scalable encoded data (BL) 1222of the base layer having a small amount of data at low quality. On theother hand, for example, in the case of notable circumstances, thescalable encoded data storage device 1202 stores the scalable encodeddata (BL+EL) 1221 having a large amount of data at high quality withoutchange.

In this way, because the scalable encoded data storage device 1202 cansave the image at high quality only in a necessary case, it is possibleto suppress the decrease of the value of the image due to thedeterioration of the image quality and suppress the increase of theamount of data, and it is possible to improve the use efficiency of thestorage region.

For example, the image capturing device 1201 is assumed to be a motoringcamera. Because content of the captured image is unlikely to beimportant when a monitoring subject (for example, an invader) is notshown in the imaged image (in the case of the normal circumstances), thepriority is on the reduction of the amount of data, and the image data(scalable encoded data) is stored at low quality. On the other hand,because the content of the imaged image is likely to be important when amonitoring target is shown as the subject 1211 in the imaged image (inthe case of the notable circumstances), the priority is on the imagequality, and the image data (scalable encoded data) is stored at highquality.

For example, whether the case is the case of the normal circumstances orthe notable circumstances may be determined by the scalable encoded datastorage device 1202 by analyzing the image. In addition, the imagecapturing device 1201 may be configured to make the determination andtransmit the determination result to the scalable encoded data storagedevice 1202.

A determination criterion of whether the case is the case of the normalcircumstances or the notable circumstances is optional and the contentof the image which is the determination criterion is optional. Ofcourse, a condition other than the content of the image can bedesignated as the determination criterion. For example, switching may beconfigured to be performed according to the magnitude or waveform ofrecorded sound, by a predetermined time interval, or by an externalinstruction such as the user's instruction.

In addition, although the two states of the normal circumstances and thenotable circumstances have been described above, the number of thestates is optional, and for example, switching may be configured to beperformed among three or more states such as normal circumstances,slightly notable circumstances, notable circumstances, and highlynotable circumstances. However, the upper limit number of states to beswitched depends upon the number of layers of the scalable encoded data.

In addition, the image capturing device 1201 may determine the number oflayers of the scalable video coding according to the state. For example,in the case of the normal circumstances, the image capturing device 1201may generate the scalable encoded data (BL) 1222 of the base layerhaving a small amount of data at low quality and supply the data to thescalable encoded data storage device 1202. In addition, for example, inthe case of the notable circumstances, the image capturing device 1201may generate the scalable encoded data (BL+EL) 1221 of the base layerhaving a large amount of data at high quality and supply the data to thescalable encoded data storage device 1202.

Although the monitoring camera has been described above as the example,the usage of the image capturing system 1200 is optional and is notlimited to the monitoring camera.

Further, the present technology can also be applied to HTTP streamingsuch as MPEG DASH in which appropriate encoded data is selected in unitsof segments from among a plurality of pieces of encoded data havingdifferent solutions that are prepared in advance and used. In otherwords, a plurality of pieces of encoded data can share informationrelated to encoding or decoding.

Further, in this specification, the example in which various kinds ofinformation such as the HRD parameter type flag, the HRD parameter, orbuffering_period_SEI and layer_buffering_period_SEI are multiplexed intoan encoded stream and transmitted from the encoding side to the decodingside has been described. However, a technique of transmitting theinformation is not limited to this example. For example, the informationmay be transmitted or recorded as individual data associated with anencoded bitstream without being multiplexed in the encoded stream. Here,the term “associate” refers to that an image included in the bitstream(which may be part of an image such a slice or a block) and informationcorresponding to the image is configured to be linked at the time ofdecoding. That is, the information may be transmitted on a separatetransmission path from an image (or bitstream). In addition, theinformation may be recorded on a separate recording medium (or aseparate recording area of the same recording medium) from the image (orbitstream). Further, the information and the image (or the bitstream),for example, may be associated with each other in an arbitrary unit suchas a plurality of frames, one frame, or a portion within the frame.

The preferred embodiments of the present disclosure have been describedabove with reference to the accompanying drawings, whilst the presentinvention is not limited to the above examples, of course. A personskilled in the art may find various alterations and modifications withinthe scope of the appended claims, and it should be understood that theywill naturally come under the technical scope of the present disclosure.

Additionally, the present technology may also be configured as below.

(1)

An image processing device including:

a receiving section configured to receive a bitstream obtained byencoding an image having at least one layer and buffer managementparameter information of each layer indicating at least one of that aparameter for managing a decoder buffer is a parameter for performing adecoding process of only a corresponding layer and that the parameterfor managing the decoder buffer is a parameter for performing a decodingprocess of a corresponding layer and a lower layer; and

a decoding section configured to decode the bitstream received by thereceiving section and generate an image.

(2)

The image processing device according to (1),

wherein the layer includes a layer and a sublayer.

(3)

The image processing device according to (1) or (2),

wherein the layer is a view of multi-view coding.

(4)

The image processing device according to (1) or (2),

wherein the layer is a layer of scalable video coding.

(5)

The image processing device according to any one of (1) to (4),

wherein the buffer management parameter information is described insupplemental enhancement information (SEI).

(6)

The image processing device according to any one of (1) to (5),

wherein the buffer management parameter information is described inbuffering_period_SE.

(7)

The image processing device according to any one of (1) to (4),

wherein parameter presence/absence information indicating a presence orabsence of the parameter for managing the decoder buffer serving as theparameter for performing the decoding process of only the correspondinglayer is described in a vps (video parameter set)_extension.

(8)

The image processing device according to any one of (1) to (7),

wherein the receiving section receives an AVC flag indicating that alayer lower than the corresponding layer is encoded by MPEG-4 Part10Advanced Video Coding (AVC) and the buffer management parameterinformation of each layer indicating that the parameter for managing thedecoder buffer is the parameter for performing the decoding process ofonly the corresponding layer.

(9)

An image processing method including:

receiving, by an image processing device, a bitstream obtained byencoding an image having at least one layer and buffer managementparameter information of each layer indicating at least one of that aparameter for managing a decoder buffer is a parameter for performing adecoding process of only a corresponding layer and that the parameterfor managing the decoder buffer is a parameter for performing a decodingprocess of a corresponding layer and a lower layer, and

decoding, by the image processing device, the received bitstream andgenerating an image.

(10)

An image processing device including:

a setting section configured to set buffer management parameterinformation of each layer indicating at least one of that a parameterfor managing a decoder buffer is a parameter for performing a decodingprocess of only a corresponding layer and that the parameter formanaging the decoder buffer is a parameter for performing a decodingprocess of a corresponding layer and a lower layer;

an encoding section configured to encode an image having at least onelayer and generate a bitstream; and

a transmitting section configured to transmit the buffer managementparameter information set by the setting section and the bitstreamgenerated by the encoding section.

(11)

The image processing device according to (10),

wherein the layer includes a layer and a sublayer.

(12)

The image processing device according to (10) or (11),

wherein the layer is a view of multi-view coding.

(13)

The image processing device according to (10) or (11),

wherein the layer is a layer of scalable video coding.

(14)

The image processing device according to any one of (10) to (13),

wherein the buffer management parameter information is described insupplemental enhancement information (SEI).

(15)

The image processing device according to any one of (10) to (14),

wherein the buffer management parameter information is described inbuffering_period_SEI.

(16)

The image processing device according to any one of (10) to (13),

wherein parameter presence/absence information indicating a presence orabsence of the parameter for managing the decoder buffer serving as theparameter for performing the decoding process of only the correspondinglayer is described in a vps (video parameter set)_extension.

(17)

The image processing device according to any one of (10) to (16),wherein the setting section sets an AVC flag indicating that a layerlower than the corresponding layer is encoded by MPEG-4 Part10 AdvancedVideo Coding (AVC) and the buffer management parameter information ofeach layer indicating that the parameter for managing the decoder bufferis the parameter for performing the decoding process of only thecorresponding layer.

(18)

An image processing method including:

setting, by an image processing device, buffer management parameterinformation of each layer indicating at least one of that a parameterfor managing a decoder buffer is a parameter for performing a decodingprocess of only a corresponding layer and that the parameter formanaging the decoder buffer is a parameter for performing a decodingprocess of a corresponding layer and a lower layer;

encoding, by the image processing device, an image having at least onelayer and generating a bitstream; and

transmitting, by the image processing device, the set buffer managementparameter information and the generated bitstream.

REFERENCE SIGNS LIST

-   100 scalable encoding device-   101 layer image encoding section-   101-1 base layer image encoding section-   101-2,101-3 enhancement layer image encoding section-   102 encoding control section-   116 lossless encoding section-   117 accumulation buffer-   127 HRD type setting section-   131 partial accumulation buffer-   132 whole accumulation buffer-   141 layer HRD parameter calculating section-   142 time layer HRD parameter calculating section-   143 HRD parameter type setting section-   144 time HRD parameter type setting section-   200 scalable decoding device-   201 layer image decoding section-   201-1 base layer image decoding section-   201-2,201-3 enhancement layer image decoding section-   202 decoding control section-   211 accumulation buffer-   212 lossless decoding section-   224 HRD type decoding section-   231 partial accumulation buffer-   232 whole accumulation buffer-   241 layer HRD parameter monitoring section-   242 time layer HRD parameter monitoring section-   243 HRD parameter type decoding section-   244 time HRD parameter type decoding section-   301 lossless encoding section-   302 buffering period SEI setting section-   311 associated parameter set setting section-   312 layer set buffer-   313 layer buffering period SEI setting section-   314 layer parameter transmission designating section-   351 lossless decoding section-   352 buffering period SEI decoding section-   361 associated parameter set decoding section-   362 layer set buffer-   363 layer buffering period SEI decoding section-   364 layer parameter transmission receiving section

1. An image processing device comprising: a receiving section configuredto receive a bitstream obtained by encoding an image having at least onelayer and buffer management parameter information of each layerindicating at least one of that a parameter for managing a decoderbuffer is a parameter for performing a decoding process of only acorresponding layer and that the parameter for managing the decoderbuffer is a parameter for performing a decoding process of acorresponding layer and a lower layer; and a decoding section configuredto decode the bitstream received by the receiving section and generatean image.
 2. The image processing device according to claim 1, whereinthe layer includes a layer and a sublayer.
 3. The image processingdevice according to claim 2, wherein the layer is a view of multi-viewcoding.
 4. The image processing device according to claim 2, wherein thelayer is a layer of scalable video coding.
 5. The image processingdevice according to claim 1, wherein the buffer management parameterinformation is described in supplemental enhancement information (SEI).6. The image processing device according to claim 5, wherein the buffermanagement parameter information is described in buffering_period_SEI.7. The image processing device according to claim 1, wherein parameterpresence/absence information indicating a presence or absence of theparameter for managing the decoder buffer serving as the parameter forperforming the decoding process of only the corresponding layer isdescribed in a vps (video parameter set)_extension.
 8. The imageprocessing device according to claim 1, wherein the receiving sectionreceives an AVC flag indicating that a layer lower than thecorresponding layer is encoded by MPEG-4 Part10 Advanced Video Coding(AVC) and the buffer management parameter information of each layerindicating that the parameter for managing the decoder buffer is theparameter for performing the decoding process of only the correspondinglayer.
 9. An image processing method comprising: receiving, by an imageprocessing device, a bitstream obtained by encoding an image having atleast one layer and buffer management parameter information of eachlayer indicating at least one of that a parameter for managing a decoderbuffer is a parameter for performing a decoding process of only acorresponding layer and that the parameter for managing the decoderbuffer is a parameter for performing a decoding process of acorresponding layer and a lower layer; and decoding, by the imageprocessing device, the received bitstream and generating an image. 10.An image processing device comprising: a setting section configured toset buffer management parameter information of each layer indicating atleast one of that a parameter for managing a decoder buffer is aparameter for performing a decoding process of only a correspondinglayer and that the parameter for managing the decoder buffer is aparameter for performing a decoding process of a corresponding layer anda lower layer; an encoding section configured to encode an image havingat least one layer and generate a bitstream; and a transmitting sectionconfigured to transmit the buffer management parameter information setby the setting section and the bitstream generated by the encodingsection.
 11. The image processing device according to claim 10, whereinthe layer includes a layer and a sublayer.
 12. The image processingdevice according to claim 11, wherein the layer is a view of multi-viewcoding.
 13. The image processing device according to claim 11, whereinthe layer is a layer of scalable video coding.
 14. The image processingdevice according to claim 10, wherein the buffer management parameterinformation is described in supplemental enhancement information (SEI).15. The image processing device according to claim 14, wherein thebuffer management parameter information is described inbuffering_period_SEI.
 16. The image processing device according to claim10, wherein parameter presence/absence information indicating a presenceor absence of the parameter for managing the decoder buffer serving asthe parameter for performing the decoding process of only thecorresponding layer is described in a vps (video parameterset)_extension.
 17. The image processing device according to claim 10,wherein the setting section sets an AVC flag indicating that a layerlower than the corresponding layer is encoded by MPEG-4 Part10 AdvancedVideo Coding (AVC) and the buffer management parameter information ofeach layer indicating that the parameter for managing the decoder bufferis the parameter for performing the decoding process of only thecorresponding layer.
 18. An image processing method comprising: setting,by an image processing device, buffer management parameter informationof each layer indicating at least one of that a parameter for managing adecoder buffer is a parameter for performing a decoding process of onlya corresponding layer and that the parameter for managing the decoderbuffer is a parameter for performing a decoding process of acorresponding layer and a lower layer; encoding, by the image processingdevice, an image having at least one layer and generating a bitstream;and transmitting, by the image processing device, the set buffermanagement parameter information and the generated bitstream.